Using In Vitro Electrophysiology to Screen Medications: Accumbal Plasticity as an Engram of Alcohol Dependence.

The nucleus accumbens (NAc) is a central component of the mesocorticolimbic reward system. Increasing evidence strongly implicates long-term synaptic neuroadaptations in glutamatergic excitatory activity of the NAc shell and/or core medium spiny neurons in response to chronic drug and alcohol exposure. Such neuroadaptations likely play a critical role in the development and expression of drug-seeking behaviors. We have observed unique cell-type-specific bidirectional changes in NAc synaptic plasticity (metaplasticity) following acute and chronic intermittent ethanol exposure. Other investigators have also previously observed similar metaplasticity in the NAc following exposure to psychostimulants, opiates, and amazingly, even following an anhedonia-inducing experience. Considering that the proteome of the postsynaptic density likely contains hundreds of biochemicals, proteins and other components and regulators, we believe that there is a large number of potential molecular sites through which accumbal metaplasticity may be involved in chronic alcohol abuse. Many of our companion laboratories are now engaged in identifying and screening medications targeting candidate genes and its products previously linked to maladaptive alcohol phenotypes. We hypothesize that if manipulation of such target genes and their products change NAc plasticity, then that observation constitutes an important validation step for the development of novel therapeutics to treat alcohol dependence.

Cell type-specific synaptic encoding of ethanol exposure in the nucleus accumbens shell.

Synaptic alterations in the nucleus accumbens (NAc) are crucial for the aberrant reward-associated learning that forms the foundation of drug dependence. Altered glutamatergic synaptic plasticity, in particular, is thought to be a vital component of the neurobiological underpinnings of addictive behavior. The development of bacterial artificial chromosome-eGFP (enhanced green fluorescent protein) transgenic mice that express eGFP driven by endogenous D1 dopamine receptor (D1R) promoters has now allowed investigation of the cell type-specific synaptic modifications in the NAc in response to drugs of abuse. In this study, we used whole-cell ex vivo slice electrophysiology in Drd1-eGFP mice to investigate cell type-specific alterations in NAc synaptic plasticity following ethanol exposure. Electrophysiological recordings were made from eGFP-expressing medium spiny neurons (D1+ MSNs) and non-eGFP-expressing (putative D2 receptor-expressing) (D1- MSNs) from the shell subregion of the NAc. We observed low frequency-induced long-term depression (1Hz-LTD) of α-amino-3-hydroxy-5-methyl-isoxazole-4-propionic acid (AMPA)-mediated excitatory postsynaptic currents (EPSCs) solely in D1+ MSNs. However, 24h following four consecutive days of in vivo chronic intermittent ethanol (CIE) vapor exposure, 1-Hz LTD was conversely observed only in D1- MSNs, and now absent in D1+ MSNs. Complete recovery of the baseline plasticity phenotype in both cell types required a full 2 weeks of withdrawal from CIE vapor exposure. Thus, we observed a cell type specificity of synaptic plasticity in the NAc shell, as well as, a gradual recovery of the pre-ethanol exposure plasticity state following extended withdrawal. These changes highlight the adaptability of NAc shell MSNs to the effects of ethanol exposure and may represent critical neuroadaptations underlying the development of ethanol dependence.

GABAergic transmission modulates ethanol excitation of ventral tegmental area dopamine neurons.

Activation of the dopaminergic (DA) neurons of the ventral tegmental area (VTA) by ethanol has been implicated in its rewarding and reinforcing effects. We previously demonstrated that ethanol enhances GABA release onto VTA-DA neurons via activation of 5-HT2C receptors and subsequent release of calcium from intracellular stores. Here we demonstrate that excitation of VTA-DA neurons by ethanol is limited by an ethanol-enhancement in GABA release. In this study, we performed whole-cell voltage clamp recordings of miniature inhibitory postsynaptic currents (mIPSCs) and cell-attached recordings of action potential firing from VTA-DA neurons in midbrain slices from young Long Evans rats. Acute exposure to ethanol (75 mM) transiently enhanced the firing rate of VTA-DA neurons as well as the frequency of mIPSCs. Simultaneous blockade of both GABA(A) and GABA(B) receptors (Picrotoxin (75 µM) and SCH50911 (20 µM)) disinhibited VTA-DA firing rate whereas a GABA(A) agonist (muscimol, 1 µM) strongly inhibited firing rate. In the presence of picrotoxin, ethanol enhanced VTA-DA firing rate more than in the absence of picrotoxin. Additionally, a sub-maximal concentration of muscimol together with ethanol inhibited VTA-DA firing rate more than muscimol alone. DAMGO (3 µM) inhibited mIPSC frequency but did not block the ethanol-enhancement in mIPSC frequency. DAMGO (1 and 3 µM) had no effect on VTA-DA firing rate. Naltrexone (60 µM) had no effect on basal or ethanol-enhancement of mIPSC frequency. Additionally, naltrexone (20 and 60 µM) did not block the ethanol-enhancement in VTA-DA firing rate. Overall, the present results indicate that the ethanol enhancement in GABA release onto VTA-DA neurons limits the stimulatory effect of ethanol on VTA-DA neuron activity and may have implications for the rewarding properties of ethanol.

Synergistic effects of the peptide fragment D-NAPVSIPQ on ethanol inhibition of synaptic plasticity and NMDA receptors in rat hippocampus.

The L1 cell adhesion molecule has been implicated in ethanol teratogenesis as well as NMDAR-dependent long-term potentiation (LTP) of synaptic transmission, a process thought to be critical for neural development. Ethanol inhibits LTP at least in part by interacting with NMDA receptors. Ethanol also inhibits L1-mediated cell adhesion in a manner that is prevented by an octapeptide, D-NAPVSIPQ (D-NAP), as well as long chain alcohols such as 1-octanol. Here we analyzed the effects of D-NAP and 1-octanol on ethanol modulation of LTP induced by theta burst stimulation in two subfields of the rat hippocampus, the dentate gyrus and area CA1. When theta burst stimulation was delivered in ethanol (50 mM), LTP was inhibited by about 50%. Surprisingly, when D-NAP (10(-7) M) and ethanol were co-applied or applied sequentially, LTP was completely absent. The effects of D-NAP were persistent, since delivery of a second theta burst stimulation following washout of D-NAP and ethanol elicited minimal plasticity. Application of D-NAP alone had no effect on LTP induction or expression. The synergistic effect of D-NAP on ethanol inhibition of LTP was concentration-dependent since D-NAP (10(-10) M) had an intermediate effect, while D-NAP (10(-13) M) had no effect on ethanol suppression of LTP. These observations were also replicated with a different ethanol antagonist, 1-octanol, in area CA1. To address the mechanisms underlying this long-lasting suppression of LTP, the sensitivity of pharmacologically isolated NMDAR extracellular field potentials to combinations of D-NAP and ethanol was determined. D-NAP (10(-7)M) alone had no effect on NMDA extracellular field potentials; however, the peptide significantly increased the inhibitory action of ethanol on NMDA extracellular field potential. The findings suggest that D-NAP and 1-octanol selectively interact with NMDA receptors in an ethanol-dependent manner, further implicating the L1 cell adhesion molecule in alcohol-related brain disorders.

DARPP-32 and regulation of the ethanol sensitivity of NMDA receptors in the nucleus accumbens.

The medium spiny neurons of the nucleus accumbens receive both an excitatory glutamatergic input from forebrain and a dopaminergic input from the ventral tegmental area. This integration point may constitute a locus whereby the N-methyl-D-aspartate (NMDA)-subtype of glutamate receptors promotes drug reinforcement. Here we investigate how dopaminergic inputs alter the ethanol sensitivity of NMDA receptors in rats and mice and report that previous dopamine receptor-1 (D1) activation, culminating in dopamine and cAMP-regulated phosphoprotein-32 kD (DARPP-32) and NMDA receptor subunit-1 (NR1)-NMDA receptor phosphorylation, strongly decreases ethanol inhibition of NMDA responses. The regulation of ethanol sensitivity of NMDA receptors by D1 receptors was absent in DARPP-32 knockout mice. We propose that DARPP-32 mediated blunting of the response to ethanol subsequent to activation of ventral tegmental area dopaminergic neurons initiates molecular alterations that influence synaptic plasticity in this circuit, thereby promoting the development of ethanol reinforcement.

Dynamics of NMDAR-mediated neurotoxicity during chronic ethanol exposure and withdrawal.

We have utilized a hippocampal brain slice explant system to assess cellular and synaptic mechanisms underlying the expression of alcohol withdrawal hyperexcitability. Previously, we observed a role for NMDA receptors in the expression of electrographic seizures (EGS) observed immediately upon withdrawal from chronic ethanol exposure in this system. One possible cellular mechanism responsible for these prior results involves NMDAR-mediated neurotoxicity, which was assessed in the present study. Explants were exposed to 35 or 75 mM ethanol for 6 or 12 days and incubated with propidium iodide (PI) to label non-viable cells and then imaged digitally. PI labeling was significantly reduced (36% of control levels) following chronic ethanol exposure (75 mM). When tested following ethanol withdrawal, PI labeling remained significantly reduced in the 75 mM exposed group. We next assessed the effect of an NMDA challenge 24 h following withdrawal. The 35 mM and 75 mM ethanol exposed groups displayed significant 6-fold and 13-fold NMDAR-mediated increases in PI labeling respectively; control explants displayed a 3-fold increase. These data suggest that chronic ethanol exposure prior to withdrawal has a minor neuroprotective effect that slightly diminishes within 24 h of ethanol withdrawal. Furthermore, the data indicate that direct NMDAR activation is required for induction of ethanol withdrawal neurotoxicity.

G-protein-coupled inwardly rectifying potassium channels are targets of alcohol action.

G-protein-coupled inwardly rectifying potassium channels (GIRKs) are important for regulation of synaptic transmission and neuronal firing rates. Because of their key role in brain function, we asked if these potassium channels are targets of alcohol action. Ethanol enhanced function of cerebellar granule cell GIRKs coupled to GABAB receptors. Enhancement of GIRK function by ethanol was studied in detail using Xenopus oocytes expressing homomeric or heteromeric channels. Function of all GIRK channels was enhanced by intoxicating concentrations of ethanol, but other, related inwardly rectifying potassium channels were not affected. GIRK2/IRK1 chimeras and GIRK2 truncation mutants were used to identify a region of 43 amino acids in the carboxyl (C) terminus that is critical for the action of ethanol on these channels.

In vivo activation and in situ BDNF-stimulated nuclear translocation of mitogen-activated/extracellular signal-regulated protein kinase is inhibited by ethanol in the developing rat hippocampus.

In order to test the hypothesis that ethanol (EtOH)-induced changes in growth factor signal transduction contribute to the teratogenic effects of EtOH in the developing brain, neonatal rat pups were administered a single dose of EtOH during the brain growth spurt (5 days of age, PN5). Hippocampal mitogen-activated/extracellular signal-regulated protein kinase (MAPK/ERK) activation was analyzed one to 6 h after exposure by electrophoretic-mobility shift assay combined with western blot. Brain-Derived Neurotrophic Factor (BDNF) was used to stimulate ERK in hippocampal slices prepared from PN5 pups and activation and cellular localization was determined with immunofluorescence combined with confocal microscopy. EtOH decreased ERK activation in vivo and decreased nuclear translocation of BDNF-stimulated ERK in situ. These data suggest EtOH-induced inhibition of growth factor signaling may contribute to the development of fetal alcohol syndrome and alcohol-related birth defects.

Evidence for a causative role of N-methyl-D-aspartate receptors in an in vitro model of alcohol withdrawal hyperexcitability.

Synaptic mechanisms underlying hyperexcitability due to withdrawal from chronic ethanol exposure were investigated in a hippocampal explant model system using electrophysiological techniques. Whole-cell voltage clamp recordings from CA1 pyramidal cells demonstrated that acute ethanol exposure inhibited N-methyl-D-aspartate receptor (NMDAR)-mediated excitatory postsynaptic currents by over 40%. Chronic ethanol exposure for 6 to 11 days at 35 or 75 mM induced no differences from control explants in the fast component of the population synaptic response (non-NMDAR-mediated). Prolonged field potential recordings (to 10 hr) were used to monitor the withdrawal process in vitro. Ethanol-exposed explants from both 35 and 75 mM groups displayed an increase (60% and 89%, respectively) in the NMDAR-mediated component of synaptic transmission on withdrawal from chronic exposure. Prolonged tonic-clonic electrographic seizure activity was consistently observed after ethanol withdrawal only after the increase in NMDAR function. This hyperexcitability was inhibited by the NMDAR antagonist D-2-amino-5-phosphonovaleric acid and returned once the NMDAR component was reestablished after antagonist washout. In situ hybridization studies suggest that expression of NR2B subunit mRNA may be enhanced in explants after chronic ethanol exposure. No lasting differences were observed in the NMDAR component after acute in vitro ethanol exposure and withdrawal. These data suggest that the occurance of ethanol withdrawal hyperexcitability in this system may be directly dependent on alterations in NMDAR function after chronic exposure. Since this region and others that contain ethanol sensitive NMDARs may serve as epileptic foci, long term alterations in NMDAR function may be expected to generate paroxysmal depolarizing shifts underlying ictal events after withdrawal from ethanol exposure.

Survival and functional demonstration of interregional pathways in fore/midbrain slice explant cultures.

An important general question in neurobiology concerns the development and expression of the rich context of neuronal phenotypes, especially in relation to the diverse patterns of connectivity. Organotypic cultures of brain slices may offer distinct advantages for such studies if such a preparation survives, maintains a wide diversity of neuronal phenotypes and displays appropriate synaptic connections between regions. To address these requirements, we utilized long-term organotypic cultures of intact horizontal slices of rat forebrain and midbrain and assessed a variety of markers of phenotype in combination with functional tests of connectivity. This explant preparation displayed a distinct viability requirement such that the greatest explant survival was seen in slices taken from pups of less than postnatal day 7 and was independent of N-methyl-D-aspartate channel blockade. The anatomical features of the major brain regions (e.g., neocortex, striatum, septum, hippocampus, diencephalon and midbrain) were observed in their normal boundaries. The presence of cholinergic and catecholaminergic neurons was demonstrated with acetylcholinesterase histochemistry and tyrosine hydroxylase immunohistochemistry. Labelled neurons displayed multiple, regionally-appropriate cytoarchitectures and, in some cases, could be seen to project to brain regions in a manner quite similar to that seen in vivo. Finally, the direct demonstration of spontaneous and evoked interregional excitatory synaptic transmission was made using whole-cell patch-clamp recordings from striatal neurons which revealed an intact glutamate-using corticostriatal pathway. This simple explant preparation appears to contain a rich diversity of neuronal types and synaptic organization. Therefore, this preparation appears to have several distinct advantages for basic neurobiologic research since it combines long-term culture viability and many features of mature brain including complex interregional neuronal systems.

Organotypic brain slice cultures for functional analysis of alcohol-related disorders: novel versus conventional preparations.

Assessment of long-term alterations in neural function and phenotype has usually involved culture techniques that utilize dissociated preparations. Recently, we have approached such topics in alcohol research by using brain slice cultures, also known as explant or organotypic preparations. In this symposium presentation, two preparations will be discussed, and examples of the particular advantages of these preparations will be presented in relation to alcohol research. First, we use the hippocampal explant preparation for assessment of long-term alterations in N-methyl-D-aspartate receptor (NMDAR) function due to chronic ethanol exposure and subsequent withdrawal. This preparation displays many synaptic, structural, and enzymatic phenotypes indicative of normal neural preparations. Patch clamp recordings reveal NMDAR-mediated excitatory postsynaptic current (EPSC) elicited upon stimulation of Schaffer collateral fibers and recorded from CA1 pyramidal cells. Long-term ethanol exposure followed by subsequent withdrawal resulted in a specific enhancement of NMDAR-mediated synaptic responses which preceded the expression of epileptiform events that occurred after prolonged withdrawal periods. Second, we describe a novel explant preparation, derived from horizontal slices of the entire forebrain and midbrain of the rat. These long-term explants displayed multiple normal phenotypes including Nissl, AChE, TH, and GFAP staining. Electrophysiologically, these explants displayed a functional corticostriatal pathway recorded with field and patch clamp techniques and elicited by synaptic stimulation. Taken together, these explant preparations display utility for long-term study of ethanol effects on neural systems, especially relating to withdrawal hyperexcitability as well as systems involved in drug-seeking behavior.

Glycine modulates ethanol inhibition of heteromeric N-methyl-D-aspartate receptors expressed in Xenopus oocytes.

Ethanol inhibits N-methyl-D-aspartate (NMDA) receptor-mediated responses at pharmacologically relevant concentrations, suggesting that inhibition of NMDA receptors may underlie some of the actions of ethanol in the central nervous system. We examined the ability of glycine to modulate ethanol inhibition of four recombinant heteromeric NMDA receptors (NR1a/NR2A through NR2D) expressed in Xenopus oocytes. Ethanol dose-response analysis revealed enhanced inhibitory efficacy of ethanol in the presence of subsaturating glycine concentrations at the NR1/NR2A, NR1/NR2C, and NR1/NR2D receptors. When assayed over a range of glycine concentrations, ethanol exhibited both glycine-reversible and glycine-independent inhibition of NMDA receptors. In contrast, ethanol inhibition of recombinant NMDA receptors was independent of NMDA concentration. Glycine reversal of ethanol inhibition suggested that ethanol might lower the affinity of glycine for the NMDA receptor and thereby decrease response magnitude. Consistent with this hypothesis, ethanol significantly reduced glycine affinity at NR1/NR2A and NR1/NR2C receptors. Evaluation of the glycine-independent component of ethanol inhibition demonstrated that in the presence of saturating concentrations of glycine, the NR1/NR2A and NR1/NR2B receptors were more sensitive to ethanol than the NR1/NR2C and NR1/NR2D receptors. Activation of the NR1/NR2D heteromers by NMDA and low concentrations of glycine elicited responses characterized by an initial peak followed by a lower-amplitude plateau response, which is consistent with glycine-sensitive desensitization as previously described for native NMDA receptors. In addition, nondesensitizing NR1/NR2B responses elicited in the presence of subsaturating concentrations of glycine were frequently converted into desensitizing responses by the addition of ethanol, an effect that was reversed with increasing glycine concentrations. The ability of ethanol to promote glycine-sensitive desensitization further suggests an interaction between glycine and ethanol inhibition of the NMDA receptor. Taken together, the results of the present report demonstrate that ethanol inhibition of NMDA receptors has both glycine-reversible and glycine-independent components, suggesting two distinct molecular mechanisms for ethanol inhibition of NMDA receptors.

Neuropeptide Y (18-36) modulates chromaffin cell catecholamine secretion by blocking the nicotinic receptor ion channel.

Neuropeptide Y (NPY) is a widely distributed peptide with varied activities including inhibition of [3H]NE secretion from chromaffin cells. In the present study, we investigated the mechanism through which NPY and NPY fragments inhibit nicotinic receptor induced influx of 22Na+ and 45Ca++ into bovine chromaffin cells. Fragments of NPY, including NPY13-36, NPY18-36 and NPY26-36, are more potent inhibitors of 45Ca++ and 22Na+ influx than NPY. High [K+]- and BAY K 8644-induced 45Ca++ influx and veratridine-induced 22Na+ influx are not inhibited by either NPY or NPY fragments. Thus, the site of NPY or NPY fragment action is not voltage-gated Ca++ or Na+ channels. A significant amount of acetylcholine-induced 45Ca++ influx still occurs in the presence of the voltage-gated Ca++ channel blockers: nifedipine (L-type), omega-conotoxin-GVIA (N-type) and omega-agatoxin-IVA (P-type). NPY18-36, in the presence of these channel blockers, inhibited the residual nicotinic receptor-induced Ca++ influx. The response to NPY 18-36 is not pertussis toxin sensitive. The rank orders of potency for inhibition of 45Ca++ and 22Na+ are the same: NPY18-36 > or = NPY26-36 > NPY13-36 > NPY13-36 > NPY > or = NPYfree acid. Moreover, the IC50 values for NPY18-36 inhibition of 45Ca++ influx and 22Na+ influx are similar, 0.9 x 10(-6) M and 2.03 x 10(-6) M, respectively. Regression analysis for inhibition of these two phenomena produced a correlation coefficient of .9697 (P < .0003).(ABSTRACT TRUNCATED AT 250 WORDS)

Insulin potentiates N-methyl-D-aspartate receptor activity in Xenopus oocytes and rat hippocampus.

Growth factor signal transduction pathways have recently been shown to affect voltage-gated ion channel activity. In this study we report that insulin can modulate the activity of a ligand-gated ion channel, the N-methyl-D-aspartate (NMDA) receptor. In Xenopus oocytes, brief insulin exposure rapidly potentiated NR1a/NR2A and NR1a/NR2B receptor responses 2-3 fold and weakly potentiated NR1a/NR2C and NR1a/NR2D mediated-responses. Insulin potentiation of NR1a/NR2A receptor responses was significantly blocked by staurosporine, suggesting kinase involvement in insulin action. Insulin modulation of native NMDA receptors is suggested by the observation that insulin potentiated the NMDA receptor-mediated synaptic component in hippocampal slices. Regulation of NMDA receptor activity by growth factors may account for previous observations of growth factor modulation of central nervous system excitotoxicity.

The molecular basis of NMDA receptor subtypes: native receptor diversity is predicted by subunit composition.

The relationship between four pharmacologically distinct NMDA receptor subtypes, identified in radioligand binding studies, and the recently identified NMDA receptor subunits (NR1a-g, NR2A-D) has not been determined. In this report, we demonstrate that the anatomical distribution of the four NMDA receptor subtypes strikingly parallels the distribution of mRNA encoding NR2A-D subunits. The distribution of NR2A mRNA was very similar to that of "antagonist-preferring" NMDA receptors [defined by high-affinity 3H-2-carboxypiperazine-4-yl-propyl-1-phosphonic (3H-CPP) binding sites; correlation coefficient = 0.88]. Agonist-preferring NMDA receptors localized to brain regions expressing both NR2B mRNA and NR1- mRNA (NR1 splice variant lacking insert 1). NR2C mRNA was largely restricted to the cerebellar granule cell layer, a region that displays a unique pharmacological profile. NR2D mRNA localized exclusively to those diencephalic nuclei that have a fourth, distinct pharmacological profile (typified by the midline thalamic nuclei). The pharmacology of native NMDA receptors was compared to that of heteromeric NMDA receptors expressed in Xenopus oocytes (NR1/NR2A, NR1/NR2B, NR1/NR2C). The oocyte-expressed NR1/NR2A receptor displayed a higher affinity for antagonists and a slightly lower affinity for agonists than the NR1/NR2B receptor. These patterns are analogous to those found for radioligand binding to native receptors in the lateral thalamus and medial striatum, respectively. NMDA receptors in the lateral thalamus (with a high density of NR2A subunit mRNA) displayed higher affinity for antagonists and a lower affinity for agonists than did NMDA receptors of the medial striatum (a region rich in NR2B mRNA). Relative to the NR1/NR2A and NR1/NR2B receptors, oocyte-expressed NR1/NR2C receptors had a lower affinity specifically for both D-3-(2-carboxypiperazin-4-yl)-1-propenyl-1-phosphonic acid (D-CPPene) and homoquinolinate (HQ). This pattern was identical to that observed for cerebellar (NR2C-containing) versus forebrain (NR2A- and NR2B-containing) NMDA receptors. Taken together, the data in this report suggest that the four previously identified native NMDA receptor subtypes differ in their NR2 composition. Furthermore, the NR2 subunits significantly contribute to the anatomical and pharmacological diversity of NMDA receptor subtypes.

Potentiation of N-methyl-D-aspartate receptor-dependent afterdischarges in rat dentate gyrus following in vitro ethanol withdrawal.

The contribution of NMDA receptors to neuronal hyperexcitability following in vitro ethanol withdrawal was examined using afterdischarges (ADs) in rat dentate gyrus as a model system. ADs were evoked by high frequency stimuli and blocked by N-methyl-D-aspartate (NMDA) receptor antagonists. Ethanol (75 mM) inhibited ADs, and following in vitro ethanol withdrawal, the duration of afterdischarges was significantly enhanced (37 +/- 2%, n = 21). Therefore, in vitro ethanol exposure with subsequent withdrawal is associated with an enhancement of NMDA receptor-dependent afterdischarges. These results are consistent with the involvement of NMDA receptors in ethanol withdrawal hyperexcitability.

Ethanol inhibits tetraethylammonium chloride-induced synaptic plasticity in area CA1 of rat hippocampus.

Dendritic recordings of the rat hippocampal formation were used to assess the ability of ethanol to inhibit the induction of synaptic plasticity due to bath application of the K+ channel blocker, tetraethylammonium chloride (TEA). Brief application of TEA resulted in the enhancement of the population excitatory postsynaptic potential (EPSP) slope by an average of 26 +/- 3% over the pre-TEA baseline. However, coapplication of TEA and ethanol (100 mM) resulted in enhancement of only 10 +/- 2% of the EPSP slope. These data suggest that LTP (long-term potentiation) due to the activation of voltage-gated Ca2+ channels is also inhibited by ethanol.

Attenuation of hippocampal long-term potentiation by ethanol: a patch-clamp analysis of glutamatergic and GABAergic mechanisms.

Long-term potentiation of synpatic transmission (LTP) of the perforant path--dentate gyrus synapse is induced by 5 Hz, theta-like stimulation patterns. Such stimuli induce plasticity that is most likely driven by a decrease in synaptic inhibition (disinhibition) mediated by GABAB autoreceptors. In the present study, we demonstrate that LTP induced in this manner is completely antagonized by ethanol. In order to determine the site of ethanol inhibition of LTP induced by theta-like stimulation, we combined slice patch recordings with pharmacologic isolation of the individual glutamatergic and GABAergic synaptic currents. The present experiments revealed that ethanol inhibited NMDA receptor-mediated synaptic currents without potentiation of GABAA currents or attenuation of GABAB-mediated fading of GABAA synaptic currents. These observations with ethanol contrasted with the actions of the water-soluble benzodiazepine midazolam, which strongly potentiated GABAA synaptic currents, reversed the effect of GABAB-mediated fading of GABAA synaptic currents, and therefore blocked the resulting NMDA synaptic currents. These data indicate that the effects of ethanol on long-term changes in synaptic strength in the rat hippocampal formation are due primarily to an action at the NMDA receptor-channel complex.

Antiepileptic effects of GABAb receptor activation in area CA3 of rat hippocampus.

The role of GABAb receptor activation in the expression of both interictal and ictal phenomena was investigated in slices of area CA3 of the rat hippocampal formation. Interictal-like bursts occurred following application of high frequency trains to the Schaffer collaterals. When two bursts were triggered using paired stimuli, profound depression of the second burst was seen 150-600 ms following the first burst. GABAb receptor antagonists potently reversed the paired pulse depression of the interictal-like bursts. Reversal of the paired depression was also accomplished by increasing the extracellular concentration of K+ by 2-3 mM. Additional experiments were performed in area CA3 to determine the role of GABAb receptor activation on the expression of ictal phenomena. Electrographic seizures (EGSs) were induced by application of high frequency trains. 2-Hydroxy-saclofen (200 microM) significantly decreased the duration of trains required to elicit EGSs. Taken together, these data suggest that GABAb receptor activation has potent inhibitory effects on both ictal and interictal-like events.

Proconvulsant and anticonvulsant properties of ethanol: studies of electrographic seizures in vitro.

Recent studies have demonstrated that ethanol is a potent blocker of N-methyl-D-aspartate (NMDA) receptor mediated responses. It is well known that neuroplasticity processes depend on the activation of the NMDA type of excitatory amino acid receptor. We have used an in vitro model of electrographic seizures (EGS), a neuroplasticity process, to examine the effect of varying ethanol concentrations. In the present experiment, slices of rat hippocampus were electrically stimulated to produce stimulus train-induced epileptiform bursting in area CA3. EGS duration and intensity was enhanced by 10 mM ethanol, whereas increasing the concentration of ethanol (60-300 mM) attenuated established EGSs. Ethanol also raised the threshold to elicit an EGS. Removal of low ethanol concentrations resulted in a hyperexcitable state, with increased EGS duration and intensity. These results reflect acute biphasic effects of ethanol across concentrations, and withdrawal hyperexcitability. The effects of ethanol on EGSs, at concentrations which elicit intoxication but not anesthesia (< 75 mM), resemble the actions produced by NMDA antagonists on EGSs. Therefore the effects of ethanol on stimulus train-induced EGSs may be mediated through an action at the NMDA receptor complex.