Ethanol-induced Cl- flux in rat cerebellar granule cells as measured by a fluorescent probe

Humulone Modulation of GABAA Receptors and Its Role in Hops Sleep-Promoting Activity

Humulus lupulus L. (hops) is a major constituent of beer. It exhibits neuroactive properties that make it useful as a sleeping aid. These effects are hypothesized to be mediated by an increase in GABAA receptor function. In the quest to uncover the constituents responsible for the sedative and hypnotic properties of hops, recent evidence revealed that humulone, a prenylated phloroglucinol derivative comprising 35-70% of hops alpha acids, may act as a positive modulator of GABAA receptors at low micromolar concentrations. This raises the question whether humulone plays a key role in hops pharmacological activity and potentially interacts with other modulators such as ethanol, bringing further enhancement in GABAA receptor-mediated effects of beer. Here we assessed electrophysiologically the positive modulatory activity of humulone on recombinant GABAA receptors expressed in HEK293 cells. We then examined humulone interactions with other active hops compounds and ethanol on GABA-induced displacement of [3H]EBOB binding to native GABAA receptors in rat brain membranes. Using BALB/c mice, we assessed humulone's hypnotic behavior with pentobarbital- and ethanol-induced sleep as well as sedation in spontaneous locomotion with open field test. We demonstrated for the first time that humulone potentiates GABA-induced currents in α1β3γ2 receptors. In radioligand binding to native GABAA receptors, the inclusion of ethanol enhanced humulone modulation of GABA-induced displacement of [3H]EBOB binding in rat forebrain and cerebellum as it produced a leftward shift in [3H]EBOB displacement curves. Moreover, the additive modulatory effects between humulone, isoxanthohumol and 6-prenylnaringenin were evident and corresponded to the sum of [3H]EBOB displacement by each compound individually. In behavioral tests, humulone shortened sleep onset and increased the duration of sleep induced by pentobarbital and decreased the spontaneous locomotion in open field at 20 mg/kg (i.p.). Despite the absence of humulone effects on ethanol-induced sleep onset, sleep duration was increased dose-dependently down to 10 mg/kg (i.p.). Our findings confirmed humulone's positive allosteric modulation of GABAA receptor function and displayed its sedative and hypnotic behavior. Humulone modulation can be potentially enhanced by ethanol and hops modulators suggesting a probable enhancement in the intoxicating effects of ethanol in hops-enriched beer.

Effects of ethanol on sensory stimulus-evoked responses in the cerebellar molecular layer in vivo in mice

Overdose intake of ethanol can impair cerebellar cortical neurons to integrate and transfer external information, resulting in a dysfunction of cerebellar motor regulation or cerebellar ataxia. However, the mechanisms underlying ethanol-impaired transfer of sensory information from cerebellar cortical molecular layer neurons remain unclear. In the present study, we investigated the effects of ethanol on sensory stimulation-evoked responses in the cerebellar molecular layer of urethane-anesthetized mice, by electrophysiological and pharmacological methods. Our results demonstrated that air-puff stimulation (30 ms, 50-60 psi) of the ipsilateral whisker-pad evoked field potential responses in the molecular layer of the cerebellar cortex folium Crus II, which expressed a negative component (N1) followed by a gamma-aminobutyric acid receptor A (GABAA)-mediated positive component (P1). Cerebellar surface perfusion of ethanol between 2 and 5mM did not change the latency of the evoked responses and the amplitude of N1, but enhanced the amplitude and the area under the curve of P1. Interestingly, high concentrations (>20mM) of ethanol induced a significantly decrease in the amplitude and area under the curve of P1. Furthermore, high concentration ethanol (300 mM) significantly decreased the rise in tau and tau decay value of P1, whereas low concentration ethanol (2-5mM) significantly increased these values of P1. Inhibition of GABAA receptor activity reversed P1 and also abolished the effects of ethanol on sensory stimulation-evoked responses. These results indicated that ethanol induced a bidirectional effect on the sensory stimulation-evoked GABAergic responses in the cerebellar cortical molecular layer, suggesting that acute alcohol intake impacted the sensory information processing of cerebellar cortex.

Ethanol attenuates sensory stimulus-evoked responses in cerebellar granule cells via activation of GABA(A) receptors in vivo in mice

Acute alcohol intoxication affects cerebellar motor regulation possibly by altering the transfer and integration of external information in cerebellar cortical neurons, resulting in a dysfunction of cerebellar motor regulation or a cerebellar atexia. However, the synaptic mechanisms of ethanol induced impairments of sensory information processing in cerebellar cortical neurons are not fully understand. In the present study, we used electrophysiological and pharmacological methods to study the effects of ethanol on the sensory stimulation-evoked responses in cerebellar granule cells (GCs) in vivo in urethane anesthetized mice. Air-puff stimulation of the ipsilateral whisker-pad evoked stimulus-on (P1) and stimulus-off responses (P2) in GCs of cerebellar Crus II. Cerebellar surface perfusion of ethanol did not alter the onset latency of the sensory stimulation-evoked responses, but reversible reduced the amplitude of P1 and P2. The ethanol-induced reduction of the GCs sensory responses was concentration-dependent. In the presence of ethanol, the mean half-width, area under curve, rise Tau and decay Tau of P1 were significantly decreased. Blockade of gamma-aminobutyric acid type A (GABA(A)) receptors activity induced an increase in amplitude of P1, and abolished the ethanol induced inhibition of the GCs sensory responses. These results indicate that ethanol inhibits the tactile evoked responses in cerebellar GCs through enhancement of GABA(A) receptors activity.

Physiology and pharmacology of alcohol: the imidazobenzodiazepine alcohol antagonist site on subtypes of GABAA receptors as an opportunity for drug development?

Alcohol (ethanol, EtOH) has pleiotropic actions and induces a number of acute and long-term effects due to direct actions on alcohol targets, and effects of alcohol metabolites and metabolism. Many detrimental health consequences are due to EtOH metabolism and metabolites, in particular acetaldehyde, whose high reactivity leads to nonspecific chemical modifications of proteins and nucleic acids. Like acetaldehyde, alcohol has been widely considered a nonspecific drug, despite rather persuasive evidence implicating inhibitory GABA(A) receptors (GABA(A)Rs) in acute alcohol actions, for example, a GABA(A)R ligand, the imidazobenzodiazepine Ro15-4513 antagonizes many low-to-moderate dose alcohol actions in mammals. It was therefore rather surprising that abundant types of synaptic GABA(A)Rs are generally not responsive to relevant low concentrations of EtOH. In contrast, delta-subunit-containing GABA(A)Rs and extrasynaptic tonic GABA currents mediated by these receptors are sensitive to alcohol concentrations that are reached in blood and tissues during low-to-moderate alcohol consumption. We recently showed that low-dose alcohol enhancement on highly alcohol-sensitive GABA(A)R subtypes is antagonized by Ro15-4513 in an apparently competitive manner, providing a molecular explanation for behavioural Ro15-4513 alcohol antagonism. The identification of a Ro15-4513/EtOH binding site on unique GABA(A)R subtypes opens the possibility to characterize this alcohol site(s) and screen for compounds that modulate the function of EtOH/Ro15-4513-sensitive GABA(A)Rs. The utility of such drugs might range from novel alcohol antagonists that might be useful in the emergency room, to drugs for the treatment of alcoholism, as well as alcohol-mimetic drugs to harness acute positive effects of alcohol.

Modulation of GABAA receptors in cerebellar granule neurons by ethanol: a review of genetic and electrophysiological studies

Cerebellar granule neurons (CGNs) receive inhibitory input from Golgi cells in the form of phasic and tonic currents that are mediated by postsynaptic and extrasynaptic gamma-aminobutyric acid type A (GABAA) receptors, respectively. Extrasynaptic receptors are thought to contain alpha6betaxdelta subunits. Here, we review studies on ethanol (EtOH) modulation of these receptors, which have yielded contradictory results. Although studies with recombinant receptors expressed in Xenopus oocytes indicate that alpha6beta3delta receptors are potently enhanced by acute exposure to low (>or=3 mM) EtOH concentrations, this effect was not observed when these receptors were expressed in Chinese hamster ovary cells. Slice recordings of CGNs have consistently shown that EtOH increases the frequency of phasic spontaneous inhibitory postsynaptic currents (sIPSCs), as well as the tonic current amplitude and noise. However, there is a lack of consensus as to whether EtOH directly acts on extrasynaptic receptors or modulates them indirectly; that is, via an increase in spillover of synaptically released GABA. It was recently demonstrated that an R to Q mutation of amino acid 100 of the alpha6 subunit increases the effect of EtOH on both sIPSCs and tonic current. These electrophysiological findings have not been reproducible in our hands. Moreover, it was shown the alpha6-R100Q mutation enhances sensitivity to the motor-impairing effects of EtOH in outbred Sprague-Dawley rats, but this was not observed in a line of rats selectively bred for high sensitivity to EtOH-induced motor alterations (Alcohol Non-Tolerant rats). We conclude that currently there is insufficient evidence conclusively supporting a direct potentiation of extrasynaptic GABAA receptors following acute EtOH exposure in CGNs.

Ethanol dual modulatory actions on spontaneous postsynaptic currents in spinal motoneurons

Recently we have shown that acute ethanol (EtOH) exposure suppresses dorsal root-evoked synaptic potentials in spinal motoneurons. To examine the synaptic mechanisms underlying the reduced excitatory activity, EtOH actions on properties of action potential-independent miniature excitatory and inhibitory postsynaptic currents (mEPSCs and mIPSCs) were studied in spinal motoneurons of newborn rats. Properties of mEPSCs generated by activation of N-methyl-D-aspartate receptors (NMDARs) and non-NMDA receptors and of mIPSCs mediated by glycine and gamma-aminobutyric acid-A receptors (GlyR and GABA(A)R) were examined during acute exposure to 70 and 200 mM EtOH. In the presence of 70 mM EtOH, the frequency of NMDAR- and non-NMDAR-mediated mEPSCs decreased to 53 +/- 5 and 45 +/- 7% (means +/- SE) of control values, respectively. In contrast, the frequency of GlyR- and GABA(A)R-mediated mIPSCs increased to 138 +/- 15 and 167 +/- 23% of control, respectively. Based on the quantal theory of transmitter release, changes in the frequency of miniature currents are correlated with changes in transmitter release, suggesting that EtOH decreased presynaptic glutamate release and increased the release of both glycine and GABA. EtOH did not change the amplitude or rise and decay times of either mEPSCs or mIPSCs, indicating that the presynaptic changes were not associated with changes in the properties of postsynaptic receptors/channels. Acute exposure to 200 mM EtOH increased mIPSC frequency two- to threefold, significantly higher than the increase induced by 70 mM EtOH. However, the decrease in mEPSC frequency was similar to that observed in 70 mM EtOH. Those findings implied that the regulatory effect of EtOH on glycine and GABA release was dose-dependent. Exposure to the higher EtOH concentration had opposite actions on mEPSC and mIPSC amplitudes: it attenuated the amplitude of NMDAR- and non-NMDAR-mediated mEPSCs to ~80% of control and increased GlyR- and GABA(A)R-mediated mIPSC amplitude by ~20%. EtOH-induced changes in the amplitude of postsynaptic currents were not associated with changes in their basic kinetic properties. Our data suggested that in spinal networks of newborn rats, EtOH was more effective in modulating the release of excitatory and inhibitory neurotransmitters than changing the properties of their receptors/channels.

A genetically encoded ratiometric indicator for chloride: capturing chloride transients in cultured hippocampal neurons

We constructed a novel optical indicator for chloride ions by fusing the chloride-sensitive yellow fluorescent protein with the chloride-insensitive cyan fluorescent protein. The ratio of FRET-dependent emission of these fluorophores varied in proportion to the concentration of Cl and was used to measure intracellular chloride concentration ([Cl-]i) in cultured hippocampal neurons. [Cl-]i decreased during neuronal development, consistent with the shift from excitation to inhibition during maturation of GABAergic synapses. Focal activation of GABAA receptors caused large changes in [Cl-]i that could underlie use-dependent depression of GABA-dependent synaptic transmission. GABA-induced changes in somatic [Cl-]i spread into dendrites, suggesting that [Cl-]i can signal the location of synaptic activity. This genetically encoded indicator will permit new approaches ranging from high-throughput drug screening to direct recordings of synaptic Cl- signals in vivo.

Fluorescence imaging of changes in intracellular chloride in living brain slices

In brain slice preparations, chloride movements across the cell membrane of living cells are measured traditionally with 36Cl- tracer methods, Cl--selective microelectrodes, or whole-cell recording using patch clamp analysis. We have developed an alternative, noninvasive technique that uses the fluorescent Cl- ion indicator, 6-methoxy-N-ethylquinolinium iodide (MEQ), to study changes in intracellular Cl- by epifluorescence or UV laser scanning confocal microscopy. In brain slices taken from rodents younger than 22 days of age, excellent cellular loading is achieved with the membrane-permeable form of the dye, dihydro-MEQ. Subsequent intracellular oxidation of dihydro-MEQ to the Cl--sensitive MEQ traps the polar form of the dye inside the neurons. Because MEQ is a single-excitation and single-emission dye, changes in intracellular Cl- concentrations can be calibrated from the Stern-Volmer relationship, determined in separate experiments. Using MEQ as the fluorescent indicator for Cl-, Cl- flux through the gamma-aminobutyric acid (GABA)-gated Cl- channel (GABAA receptor) can be studied by dynamic video imaging and either nonconfocal (epifluorescence) or confocal microscopy in the acute brain slice preparation. Increases in intracellular Cl- quench MEQ fluorescence, thereby reflecting GABAA receptor activation. GABAA receptor functional activity can be measured in discrete cells located in neuroanatomically defined populations within areas such as the neocortex and hippocampus. Changes in intracellular Cl- can also be studied under various conditions such as oxygen/glucose deprivation ("in vitro ischemia") and excitotoxicity. In such cases, changes in cell volume may also occur due to the dependence of cell volume regulation on Na+, K+, and Cl- flux. Because changes in cell volume can affect optical fluorescence measurements, we assess cell volume changes in the brain slice using the fluorescent indicator calcein-AM. Determination of changes in MEQ fluorescence versus calcein fluorescence allows one to distinguish between an increase in intracellular Cl- and an increase in cell volume.

Confocal imaging of intracellular chloride in living brain slices: measurement of GABAA receptor activity

We have developed a method using UV laser-scanning confocal microscopy and the fluorescent chloride ion indicator, 6-methoxy-N-ethylquinolinium chloride (MEQ), to image GABA-mediated changes in intracellular chloride (Cli-) in individual neurons of the rat acute brain slice. After bath-loading slices with the cell-permeant form (reduced) of MEQ, there was intense fluorescence within neurons of diverse morphologies in the hippocampus, neocortex and cerebellum. MEQ fluorescence localized to the cytosolic compartment of both the somata and proximal dendrites. MEQ fluorescence was calibrated using the ionophores nigericin and tributyltin in the presence of varying extracellular Cl- concentrations. Neuronal MEQ fluorescence was inversely related to intracellular Cl-, with a Stern-Volmer constant of 16 M-1 (50% quench by 61 mM Cl-). Application of GABA in the perfusate produced a concentration-dependent decrease in MEQ fluorescence (EC50 = 40 microM) that was blocked in the presence of the Cl- channel antagonist, picrotoxin. Bath perfusion of hippocampal slices with modulators of the GABAA receptor, pentobarbital and diazepam, potentiated the GABA-mediated response by 85 and 44%, respectively. A regional comparison identified larger GABA responses for both cerebellar Purkinje and granule cells relative to pyramidal neurons of the hippocampus and neocortex and to hippocampal interneurons. Pressure ejection of the GABAA agonist, muscimol (40 microM), from a micropipet onto individual hippocampal neurons allowed the measurement of rapid responses (1-5 s), compared to those obtained with bath application. Thus, optical imaging of [Cl-]i using MEQ and UV-laser-scanning confocal microscopy provides investigators with a new method to study GABAA pharmacology in neighboring neurons and perhaps even in the soma versus dendrites simultaneously, within living brain slices.

Glycine and GABAA receptor-mediated chloride fluxes in synaptoneurosomes from different parts of the rat brain

Strychnine-sensitive, inhibitory glycine receptors have not until lately been considered to play a significant role in neurotransmission in mammalian forebrain regions. In order to investigate the role of glycine as a neurotransmitter in brain we have measured glycine induced chloride fluxes in different adult rat forebrain areas using synaptoneurosomes and a chloride-sensitive fluorescent indicator. The results have been compared to those obtained with GABA. The synaptoneurosomes from every brain area investigated responded to both glycine and GABA with chloride fluxes in a picrotoxin sensitive manner. The effect of glycine was inhibited by strychnine, which had no effect on the GABA-induced Cl-flux. Bicuculline inhibited the effect of GABA, but had no effect on the glycine-induced Cl-flux. Addition of GABA did not affect the response to glycine and vice versa. The endogenous content of glycine and GABA in the synaptoneurosome preparations was about the same and synaptoneurosomes from every brain area investigated released both glycine and GABA upon depolarisation with KCl. The depolarisation induced release of both GABA and glycine was partly Ca(2+)-dependent and partly Ca(2+)-independent. These results indicate that glycine can induce inhibitory Cl- fluxes distinct from GABA induced fluxes in every investigated brain area and that glycine can be released upon depolarisation.

Neurochemical bases of locomotion and ethanol stimulant effects

The locomotor stimulant effect produced by alcohol (ethanol) is one of a large number of measurable ethanol effects. Ethanol-induced euphoria in humans and locomotor stimulation in rodents, a potential animal model of human euphoria, have long been recognized and the latter has been extensively characterized. Since the euphoria produced by ethanol may influence the development of uncontrolled or excessive alcohol use, a solid understanding of the neurochemical substrates underlying such effects is important. Such an understanding for spontaneous locomotion and for ethanol's stimulant effects is beginning to emerge. Herein we review what is known about three neurochemical substrates of locomotion and of ethanol's locomotor stimulant effects. Several lines of research have implicated dopaminergic, GABAergic, and glutamatergic neurotransmitter systems in determining these behaviors. A large collection of work is cited, which strongly implicates the above-mentioned neurotransmitter substances in the control of spontaneous locomotion. A smaller, but persuasive, body of evidence suggests that central nervous system processes utilizing these transmitters are involved in determining the effects of ethanol on locomotion. Particular emphasis has been placed on the mesolimbic ventral tegmental area to nucleus accumbens dopaminergic pathway, and on the ventral pallidum/substantia innominata, where GABA and glutamate have been found to play a role in altering the activity of this dopaminergic pathway. Research on ethanol and drug locomotor sensitization, increased responsiveness to the substance with repeated administration, is also reviewed as a process that may be important in the development of drug addiction.

Differential effects of GABAergic ligands in mouse and rat hippocampal neurons

Previous electrophysiological studies suggested that GABAA receptors in rat hippocampal neurons might be less sensitive to ethanol than mouse neurons. Therefore, we examined the effects of ethanol (0.5-850 mM) in cultured mouse (C57BL/6) and rat (Sprague-Dawley) neurons. In 35% of the mouse neurons, the Cl- current was potentiated by ethanol starting at 0.5 mM. In all of the rat neurons examined, on the other hand, the current was potentiated by concentrations starting at 200 mM. We also studied the effects of GABA and other GABAergic ligands. GABAA receptors in rat and mouse neurons displayed EC50s for GABA of 9 +/- 0.3 and 17 +/- 0.8 microM, respectively and ethanol did not significantly change these values. The EC50 for diazepam was 92 +/- 3 and 120 +/- 8 nM in rat and mouse, respectively. Pentobarbital enhanced the current with EC50s of 84 +/- 3 and 106 +/- 6 microM in rat and mouse, respectively. The sensitivity for Cl-218,872, which binds preferentially to the Type I benzodiazepine receptor, was similar in all the neurons. RO 15-4513, an inverse partial agonist to the benzodiazepine receptor, was not effective in reversing the potentiation of the Cl- current in rat neurons and only slightly reduced the potentiation in mouse neurons. The receptors in rat neurons were more sensitive to external Zn2+; the current was inhibited by 50% with a concentration of 93 +/- 3 and 244 +/- 9 microM in rat and mouse, respectively. Analysis of mRNA encoding for the gamma 2L receptor subunit showed similar levels in rat and mouse neurons.(ABSTRACT TRUNCATED AT 250 WORDS)

Determination of the intracellular free chloride concentration in rat brain synaptoneurosomes using a chloride-sensitive fluorescent indicator

The chloride-sensitive fluorescent indicator MQAE (N-(6-methoxyquinolyl) acetoacetyl ester) has been used for determination of the intracellular free chloride concentration in rat brain synaptoneurosomes. Loading of the synaptoneurosomes with MQAE occurs by transmembrane diffusion. Calibration of the intracellular MQAE was done by determining the correlation between fluorescence intensity and intrasynaptoneurosomal Cl- concentration in the presence of the Cl-/OH- exchanger tributyltin and the K+/H+ exchanger nigericin, starting from zero Cl- concentration. The total quenchable signal of MQAE was determined by adding KSCN in the presence of the K+ ionophore valinomycin. The correlation between the reciprocal of the fluorescence intensity and the chloride concentration was linear at least up to 50 mM Cl-. The fluorescence of freshly prepared synaptoneurosomes was then measured and the obtained value was plotted into the calibration curve and the corresponding Cl- was read. The mean intrasynaptoneurosomal chloride concentration was 14 +/- 4 mM. We also quantitatively estimated the Cl- flux after addition of the barbiturate, pentobarbitone that opens GABAA receptor-Cl(-)-channels, to the synaptoneurosomes. An addition of 1 mM pentobarbitone corresponded to an approx. 0.59 mM change in the intrasynaptoneurosomal free chloride concentration. The results show that the chloride-sensitive fluorescent indicator MQAE is a useful tool when determining intracellular chloride activity, and in quantitative determination of chloride fluxes in living cells and subcellular preparations.