Abstract
Mice lacking either the α1 or β2 subunit of the GABAA receptor were tested for ethanol, saccharin, or quinine consumption, ethanol-conditioned place preference, ethanol-conditioned taste aversion, ethanol-simulated motor activity, and handling-induced seizures following chronic consumption of an ethanol liquid diet. The α1 null mutants showed decreased ethanol and saccharin consumption, increased aversion to ethanol, and a marked stimulation of motor activity after injection of ethanol. The β2 null mutants showed decreased consumption of saccharin and quinine, but not ethanol. Surprisingly, neither mutant showed marked changes in handling induced seizures before or after withdrawal of ethanol. The unique effects of deletion of these two GABAA receptor subunits on ethanol responses are discussed in terms of the distinct changes in different populations of GABAA receptors.
A number of behavioral effects of ethanol have been attributed to actions at the GABAA receptor (for reviews, see Mehta and Ticku, 1999; Chester and Cunningham, 2002). Some of the evidence implicating the GABA receptor system in ethanol's motivational effects comes from studies showing that GABAA receptor antagonists (Hyytia and Koob, 1995) and benzodiazepine partial inverse agonists (Balakleevsky et al., 1990) consistently reduce ethanol self-administration in rats. In contrast, GABAA receptor agonists, such as muscimol and 4,5,6,7-tetrahydroisoxazolo [5,4-c]pyridin-3-ol (THIP), can increase voluntary ethanol intake and decrease withdrawal signs (Tomkins et al., 1994).
Other work proposes a role for GABAA receptors in the discriminative stimulus effects of ethanol. Thus, muscimol can substitute for ethanol when injected into the amygdala or the core of the nucleus accumbens of rats (Hodge and Cox, 1998). GABAA receptor antagonists picrotoxin and bicuculline block the stimulatory effects seen with low-dose ethanol administration as well as depressant effects noted following high-dose ethanol administration (Hinko and Rozanov, 1990; Koechling et al., 1991). Finally, a polymorphism of the γ2 subunit of the GABAA receptor has recently been associated with genetic susceptibility to ethanol-induced motor incoordination and hypothermia, conditioned taste aversion, and withdrawal (Buck and Hood, 1998). Human genetic association studies have suggested that the GABAA β2, α6, α1, and γ2 subunit genes have a role in the development of alcohol dependence (for review, see Loh and Ball, 2000). These are only examples, taken from a substantially larger literature, that implicate GABAergic neurotransmission in the in vivo actions of ethanol.
Neurons express multiple subtypes of GABAA receptors with differing subunit composition, but the physiological significance of this diversity is unknown (McKernan and Whiting, 1996). The pharmacology of a GABAA receptor is determined to some extent by its subunit composition. Thus, affinity and efficacy of benzodiazepines are influenced by α and γ subunits, but not β subunits (Wingrove et al., 1997). In contrast to benzodiazepines, effects of loreclezole and etomidate are determined by the β subunits (Stevenson et al., 1995).
Thus, different receptor subtypes may contribute to the selective effects of drugs such as ethanol and benzodiazepines on certain types of behavior. To study the physiological role of the GABAergic system, mouse strains lacking individual GABAA receptor subunits have been generated. GABAA receptor α6 (—/—) knockout mice showed rather normal locomotion and exploration in drug-free situations (Homanics et al., 1997; Jones et al., 1997). However, these mice are strongly impaired by diazepam during a learned motor task on a Rotarod when compared with wild-type controls, whereas ethanol sensitivity was not altered in the α6 (—/—) mutant mice, clearly indicating that α6 subunit-containing GABAA receptors are not responsible for the ethanol-induced motor impairment (Korpi et al., 1999). Wick et al. (2000) showed that, compared with controls, mice carrying either the γ2L or γ2S transgene developed significantly less tolerance to the ataxic effects of ethanol without any alterations in anxiety and motor activity or acute effects of benzodiazepines and alcohol. On the contrary, mice deficient for the γ2L subunit do not differ in their behavioral or electrophysiological responses to ethanol (Homanics et al., 1999). However, this mutation increases midazolam or zolpidem sleep time about 20%, whereas responses to nonbenzodiazepine agents such as etomidate and pentobarbital were unchanged (Quinlan et al., 2000). Mice lacking the γ2 subunit die shortly after birth (Gunther et al., 1995). Mice deficient for δ subunit showed reduced ethanol consumption, attenuated withdrawal from chronic ethanol exposure, and reduced anticonvulsant effects of ethanol (Mihalek et al., 2001).
Mouse lines lacking functional GABAA receptor subunits α1or β2 were recently generated (Sur et al., 2001; Kralic et al., 2002a). In both knockout mouse lines, ∼60% of the total number of GABAA receptors were lost, consistent with the idea that many brain GABAA receptors contain these two subunits. Surprisingly, α1 (—/—) and β2 (—/—) mice do not display major phenotypic abnormalities or spontaneous seizures. α1 null mutant mice showed compensatory overexpression of α2 and α3 subunits, but β2 (—/—) mice displayed a reduction of each of the six α subunits (Sur et al., 2001; Kralic et al., 2002a). Thus, these mice provide an opportunity to study the role of GABAA receptors in alcohol action, and we recently reported that deletion of these subunits reduces effects of ethanol and some other sedative hypnotic drugs on loss of righting reflex (Blednov et al., 2003). In the present study, we asked whether these two mutations would produce similar changes in other behavioral actions of ethanol or whether we could detect subunit-specific changes in actions of ethanol.
Materials and Methods
Animals. Null α1 (—/—) and β2 (—/—) allele mice were created using homologous recombination and genotyped as previously described (Sur et al., 2001). Homozygotes of the F2 generation were interbred, avoiding any brother-sister mating, and homozygous colonies of α1 (—/—), β2 (—/—), and wild type (+/+) mice were established. In this study, the mice from F6 to F7 generations of this interbreeding were used. Mice had mixed C57BL6/129SvEv genetic background.
Female mice were used for all studies and were at least 14 to 18 weeks of age at the time of analysis; within each experiment all mice were of similar age. Mice were group housed (three to five per cage) under a 12-h light/dark cycle (lights on at 7:00 AM) and provided ad libitum access to food and water. All experiments were conducted in an isolated behavioral testing room in the animal facility to avoid external distractions. All mice were allowed to recover for at least 1 week between each drug treatment. All experiments were approved by the Institutional Animal Care and Use Committee.
Alcohol Drinking. Mice were allowed to acclimate for 1 week to individual housing. Experiments were carried out in standard 7.5 × 12.5 inch cages in sliding racks. Bottles were placed vertically 3.5 inches from the back wall through two holes in the cage top. The distance between two bottles was about 1.0 inch. A feeder was placed on the front wall. Two drinking tubes were continuously available to each mouse, and tubes were weighed daily. One tube always contained water. Food was available ad libitum, and mice were weighed every 4 days. After 4 days of water consumption (both tubes), mice were offered 3% ethanol (v/v) versus water for 4 days. Tube positions were changed every day to control for position preferences. Quantity of ethanol consumed (grams per kilogram body weight per 24 h) was calculated for each mouse, and these values were averaged for every concentration of ethanol. Immediately after 3% ethanol, a choice between 6% (v/v) ethanol and water was offered for 4 days, then 9% (v/v) ethanol for 4 days, and, finally, 12% (v/v) ethanol versus water for 4 days.
Preference for Nonalcohol Tastants. Wild-type or knockout mice were also tested for saccharin and quinine consumption. One tube always contained water and the other contained the tastant solution. Mice were serially offered saccharin (0.033 and 0.066%) and quinine hemisulfate (0.015, 0.03, 0.06, and 0.1 mM), and intakes were calculated. Each concentration was offered for 4 days, with bottle position changed every day. Within each tastant, the low concentration was always presented first, followed by the higher concentrations. Between tastants, mice had two bottles with water for 2 weeks.
Conditioned Place Preference. Four identical acrylic boxes (30 × 15 × 15 cm) (MED Associates, St. Albans, VT) were separately enclosed in ventilated, light- and sound-attenuating chambers (MED Associates). Each box has two compartments separated by a wall with a door. Compartments have a different type of floor (grid or wire mesh). Infrared light sources and photodetectors were mounted opposite each other at 2.5-cm intervals along the length of each box, 2.2 cm above the floor. Occlusion of the infrared light beams was used to measure general activity and location of the animal (left or right) within the box. Total activity counts and location of the animal (left or right compartment) within the box were recorded by a computer. The floors and the inside of the boxes were wiped with a damp sponge, and the litter paper beneath the floors was changed between animals. The main principles of conditioned place preference procedure have been described earlier (Cunningham, 1993). Briefly, the place-conditioning study involved two habituation sessions, eight conditioning sessions, and one test session. For the habituation session, mice received an injection of saline immediately before being placed in the conditioning box for 5 min on a smooth paper floor. During the habituation session, both compartments were available for mice. The purpose of the habituation session was to reduce the stress associated with the novelty of experimental procedures and exposure to the apparatus. Mice were not exposed to the distinctive floor textures to avoid latent inhibition. For conditioning, mice were randomly assigned to two groups: saline (control) and ethanol (2.0 g/kg i.p.) (n = 10–14/dose group). Within the ethanol group, mice were randomly assigned to one of two conditioning subgroups, grid+ (GRID+) or grid— (GRID—), and exposed to a Pavlovian differential conditioning procedure. On alternating days, mice in the GRID+ group received an injection of ethanol (2 g/kg) immediately before a 5-min session on the grid floor (CS+ sessions). On intervening days, these mice received saline immediately before exposure to the wire mesh floor (CS— sessions). Conversely, mice in the GRID— group received ethanol paired with the wire mesh floor and saline paired with the grid floor. Mice from the control group received a saline injection before being placed on either the grid floor or the wire mesh floor (alternative days). During conditioning trials, all mice had access only to one of two compartments of the apparatus. For the 30-min test session, all mice received injection of saline. Both compartments of each box were available for exploration during test session.
Conditioned Taste Aversion. Subjects were adapted to a water restriction schedule (2 h of water per day) over a 7-day period. At 48-h intervals over the next 10 days, all mice received 1-h access to a solution of saccharin [0.15% (w/v) sodium saccharin in tap water]. Immediately after 1-h access to saccharin, mice received injections of saline or ethanol (2.5 g/kg). All mice also received 30-min access to tap water 5 h after each saccharin access period to prevent possible dehydration. Two-hour access to tap water was given during intervening days.
Chronic Alcohol Diet. Mice were individually housed and given an ethanol-containing liquid diet (Bio-Serv, Frenchtown, NJ) (0% EtOH for 2 days, 2.3% EtOH for 2 days, 4.5% EtOH for 2 days, and 6.0% EtOH for 5 days) (Snell et al., 1996). Concentrations of alcohol are expressed as volume per volume. Pair-fed control mice were given a volume of a control diet (with maltodextrin equicalorically replacing the ethanol) equal to the average volume that the ethanol-fed mice had consumed on the previous day. Because the mutant mice consumed more of the ethanol diet than did the wild-type mice, a “matched” variant of the diet was used in a subsequent experiment. Mutant mice were given the average volume of the ethanol-liquid diet that the ethanol-fed wild-type mice had consumed 1 day before. Handling-induced convulsions (HICs) were scored from 0 to 7 as previously described (Crabbe et al., 1991). Briefly, beginning at 7:00 AM on the 11th day (9-day ethanol diet), ethanol-containing diet was replaced with control diet. Animals were scored for HICs each2hfor the first 4 h, then hourly for another 8 h after withdrawal, and then at 23 and 24 h after withdrawal. Animals were weighed every other day of ethanol exposure. The volume of diet consumed was recorded daily and calculated per kilogram of body weight as well as by amount of consumed ethanol.
Spontaneous Motor Activity Testing. Locomotor activity was measured in standard mouse cages with Opto-microVarimex (Columbus Instruments, Columbus, OH). Activity was monitored by six light beams placed along the width of the cage at 2.5-cm intervals, 1.5 cm above the floor. Each cage had bedding and food and was covered by a heavy plastic lid with holes for ventilation and bottles of water. Each mouse was prehabituated to the experimental cage for 4 h. Next, mice were removed from the experimental cages, weighed, and injected with ethanol or saline (i.p.). After ethanol administration, mice were placed immediately in individually prehabituated cages, and the activity was monitored every 5 min for 30 min. The activity recording system provides three different measures of activity. “Total activity” is the total number of beam breaks. “Ambulatory activity” is the number of new beam breaks. Therefore, ambulatory activity will ignore the repeated breaking of the same beam, which can be caused by scratching, grooming, digging, and other stereotypic behaviors. The latter is termed “small movement” activity and is obtained by subtraction of ambulatory activity from total activity.
Alcohol Injections. All alcohol (Aaper Alcohol and Chemical, Shelbyville, KY) solutions were made in saline (20%, v/v) and injected i.p. with a volume of 0.2 ml/10 g of body weight. Control mice received the same volume of saline.
Alcohol Metabolism. Animals were given a dose of ethanol (4.0 g/kg i.p.), and blood samples were taken from the retro-orbital sinus in 15, 60, 120, 180, and 240 min after injection. Blood alcohol concentration values, expressed as milligrams of ethanol per milliliter of blood were determined spectrophotometrically by an enzymatic assay (Lundquist, 1959).
Statistical Analysis. Data are reported as the mean ± S.E.M. value. The statistics software program GraphPad Prism (GraphPad Software, Inc., San Diego, CA) was used throughout. To evaluate differences between groups, analysis of variance (one-way ANOVA or two-way ANOVA with Bonferroni post hoc analysis) and Student's t test with Dunnett's correction for multiple comparisons were carried out.
Results
Ethanol Preference. We first asked whether loss of α1or β2 subunits of GABAA receptors changes alcohol consumption. In a two-bottle free-choice paradigm in which mice could drink either water or an ascending series of ethanol concentrations (0, 3, 6, 9, 12, and 15%), mice lacking α1 subunits displayed significantly reduced preference for ethanol as well as a reduction in the amount of ethanol consumed. β2 (—/—) mutant mice showed no change in ethanol consumption or preference (Fig. 1, a and b). Both mutants consumed more water than did the control mice (Fig. 1c).
Preference for Nonalcohol Tastants. Two weeks after the ethanol drinking study, the same mice were tested for saccharin (sweet) or quinine (bitter) consumption in a two-bottle choice paradigm using an order-balanced experimental design. α1 (—/—) and β2 (—/—) null mutant mice showed significantly reduced preference for saccharin compared with control mice (Fig. 2a), as well as a reduction in consumption of the saccharin solution (Fig. 2c). The water intake of both mutant mice was similar to that of wild-type mice (Fig. 2e). β2(—/—) null mutant mice showed significantly higher avoidance to quinine and lower intake of the quinine solution than did wild-type or α1 (—/—) mice (Fig. 2, b and d). In contrast, β2 (—/—) null mutant mice showed increased intake of water compared with wild-type mice (Fig. 2f).
Place Conditioning. After the control saline injections, all three genotypes spent substantially more time on the grid floor than on the wire mesh floor (Fig. 3a). Because of this preference for one type of floor, we calculated place conditioning only for the group of mice injected with ethanol paired with their less favorite type of floor, wire mesh (GRID—). The percentage of time spent on the wire mesh floor by saline- and ethanol-injected mice of each genotype is shown in Fig. 3b. As can be seen, all three genotypes spent more time on the wire mesh floor when it was paired with ethanol than when paired with saline, reflecting development of conditioned place preference. Comparisons between the saline and ethanol subgroups showed that wild-type and α1(—/—) knockout mice developed stronger conditioned place preference than did β2 (—/—) knockout mice. However, it should be noted that conditioned place preference for ethanol was not obtained with the GRID+ condition because of the high initial preference of the mice for this floor.
Mean activity during each 5-min ethanol (CS+) and saline (CS—) conditioning trial is depicted in Fig. 3, c and d. Ethanol produced an increase in activity relative to saline in α1(—/—) knockout and wild-type mice. However, in wild-type mice, ethanol-induced motor activation was revealed only at the third and fourth conditioned trials, whereas in α1 null mutant mice, ethanol stimulated motor activity beginning from the first trial. In β2 (—/—) knockout females, the first injection of ethanol decreased the activity in comparison with the saline-injected group. Activity on saline trials was decreased across trials in all three genotypes. Comparing the motor activity only in CS+ trials also showed significant differences between α1 (—/—) knockout and wild-type mice.
Because strain differences in basal activity complicate interpretation of the ethanol-stimulated activity, ethanol data were also analyzed as the difference between activity on each CS+ and the corresponding CS— trial. This analysis indicated a consistently greater ethanol-induced activation in α1 (—/—) knockout mice compared with wild-type mice, whereas β2 (—/—) null mutant females were less sensitive to the ethanol-stimulated effect than were wild-type mice (Fig. 3e).
Activity levels during the preference test mirrored genotype differences observed on saline conditioning trials. Mean ± S.E.M. activity rates were 1529 ± 151, 842 ± 111, and 3628 ± 227 for wild-type mice, α1 (—/—), and β2 (—/—) knockout mice, respectively. One-way ANOVA showed a significant genotype effect (p < 0.01); follow-up comparisons indicated that all pair-wise differences were significant (Bonferroni-corrected p values <0.01).
Conditioned Taste Aversion. Consumption of saccharin on trial 1 (before conditioning) was greatest for wild-type and less for α1 and β2 null mutant mice (Fig. 4a). To attempt to correct for these initial differences in saccharin intake and to facilitate presentation of the data, intake was calculated as a percentage of the trial 1 consumption for each subject by dividing the amount of saccharin solution consumed on subsequent conditioning trials by amount of saccharin solution consumed on trial 1 (before conditioning). Ethanol-saccharin pairings produced reductions in saccharin intake across trials, indicating the development of CTA in all genotypes. However, α1 null mutant mice developed stronger CTA than did wild-type mice, whereas the CTA developed by β2 null mutant mice was similar to that in wild-type mice (Fig. 4b).
Spontaneous Locomotion. We studied effects of ethanol on motor activity in the home cage after habituation. β2 knockout mice demonstrated higher baseline (saline injection) motor activity than did wild-type and α1 null mutant mice, whereas the level of basal (saline injection) motor activity of α1 (—/—) mice was lower than that in wild-type mice (Fig. 5, a and b). A range of ethanol doses enhanced motor activity in α1 (—/—) mice, but only one of these doses was effective in wild-type mice, and there was no effect of ethanol in β2 null mutant mice (Fig. 5b). In an attempt to correct for baseline differences, ethanol effects were normalized by setting the activity after saline injection to 100% for each genotype (Fig. 5c). In wild-type mice, ethanol caused only a weak increase in motor activity and only at a dose of 2 g/kg. In contrast, ethanol produced a very strong motor activation over a range of doses (1.5–2.5 g/kg) in α1 (—/—) knockout mice. Ethanol did not stimulate motor activity in β2 null mutant mice (Fig. 5c). Motor activity was also measured as ambulation and small movement, as described under Materials and Methods. These measures were quite similar and showed the same changes [increased basal activity in β2 (—/—) knockout mice, increased ethanol stimulation in α1 null mutant mice] as was detected by the measure of total activity presented in Fig. 5.
Chronic Alcohol Consumption. The basal HIC score measured in naive β2 (—/—) null mutant mice was significantly higher than in wild-type mice (1.97 + 0.15 and 1.46 + 0.17 for mutant and wild-type mice, respectively). Chronic ethanol exposure followed by withdrawal of ethanol produced withdrawal seizures, as measured by the HIC score (Fig. 6a). The β2 (—/—) null mutant mice showed a significant increase in area under the HIC withdrawal curve compared with both α1 knockout and wild-type mice (Fig. 6c). Pair-fed mice did not show genotype differences in HIC score or in area under the HIC withdrawal curve (Fig. 6, b and d). The intake of ethanol was higher in β2 (—/—) knockout mice than in wild-type mice (Fig. 7, a and b). In addition, the pattern of consumption was somewhat different, with the β2 (—/—) null mice showing their highest level of alcohol intake on the 3rd day, and consumption declined thereafter, reaching levels similar to those of the wild-type group on the last day (Fig. 7). Consistent with this decrease in ethanol intake toward the end of the study period, the β2 (—/—) mutant mice showed elevated HIC scores at the time of withdrawal (Fig. 6a). Taken together, these results suggest that β2 (—/—) mutant mice limited consumption during the night and began withdrawal before the other groups and before the alcohol-containing diet was removed.
Ethanol Metabolism. There were no differences in metabolism of ethanol between wild-type and either of the knockout mice (data not shown).
Discussion
Because deletion of either the α1 or β2 subunit produced a similar loss of GABAA receptor binding (Sur et al., 2001) and function (measured in cortex by chloride flux; Blednov et al., 2003), one might expect to see similar behavioral and pharmacological phenotypes in the two lines of mutant mice. However, this is not the case; of the 11 behaviors listed in Table 1, only 2 (ethanol loss of righting reflex and saccharin preference drinking) showed the same direction of change in both α1 and β2 null mutant mice. Thus, it is clear that differences between the two mutants are more important than the similar loss of receptor number and function. The key difference is likely the more selective changes produced by deletion of α1 as compared with the more global effects of β2 deletion. Sur et al. (2001) concluded that deletion of α1 did not alter the amount of receptors containing α2-5, and produced a 38% loss of the small population of receptors containing the α6 subunit, thus resulting in a fairly selective deletion of receptors containing α1 subunits. In contrast, deletion of the β2 subunit produced a loss of only 60% of the receptors containing α1, but additional depletion of 39 to 69% of receptors containing α2-6 (Sur et al., 2001). Thus, behaviors affected in the α1 mutants but not in the β2 null animals are likely mediated predominantly by α1-containing receptors, whereas in β2 mutants, receptors containing α2-5 may contribute significantly, in addition to α1, to the altered behavior. From this classification, we propose that decreased ethanol preference drinking is caused by increased conditioned taste aversion, which is due to loss of α1, and that increased motor activity after ethanol is also caused by loss of α1. The loss of α2-5 receptors may be responsible for the high baseline activity and decreased quinine preference drinking seen in the β2 null mice (Table 1). These behavioral changes are evaluated in detail in the remainder of the Discussion.
Our demonstration of decreased alcohol preference in mice lacking α1 subunits agrees with a considerable literature on the importance of GABAA receptors in alcohol intake. For example, central injection of competitive GABAA receptor antagonists significantly decreased ethanol operant responding (Hyytia and Koob, 1995; June et al., 1998). Acute injection of negative allosteric modulators of the GABAA receptor (inverse agonists) strongly decreased ethanol consumption in the two-bottle choice paradigm (Wegelius et al., 1994). Treatment with the GABAA agonist THIP was shown to enhance the acquisition of voluntary ethanol consumption in laboratory rats (Smith et al., 1992) and increase preference for ethanol over water (Boyle et al., 1993). In contrast, preference for ethanol over water was decreased following the administration of picrotoxin (Boyle et al., 1993). However, these compounds are “nonselective” GABA drugs and are therefore not capable of dissecting out potential roles of specific GABAA receptor subunits in regulating ethanol-seeking behaviors There are some recent data that suggest the importance of α1 subunit, include the demonstration that WHP (Warsaw High-Preferring) rats treated intracerebroventricularly with antisense oligodeoxynucleotide derived from α1 subunit of the GABAA receptor had decreased ethanol intake after 4 to 5 days of treatment (Malatynska et al., 2001). Also, Harvey et al. (2002) showed that bilateral microinfusion of 3-propoxy-β-carboline (α1 subunit-specific mixed agonist-antagonist) in the ventral pallidum produced marked reduction in alcohol-maintained responding in alcohol-preferring (P) rats. Recently, Chester and Cunningham (2002) suggested that blockade of GABAA receptor may produce changes in the rewarding and aversive effects of ethanol concurrently by removing a normal inhibitory influence of GABA in brain areas that mediate ethanol reward and aversion.
A key question is whether differences in intake of alcohol in our mutant mice simply reflect differences in perception of tastes. Although both knockout strains showed a similar and modest decrease in consumption of sweet saccharin solutions, only the α1 (—/—) mice showed a decrease in ethanol consumption. In addition, β2(—/—) null mutant mice (but not α1(—/—) mice) showed avoidance for bitter quinine solutions, but this mutant strain was not different from wild-type mice in consumption of alcohol. Taken together, these results are consistent with our finding that deletion of the α1 subunit of GABAA receptor leads to avoidance of voluntarily ethanol consumption, likely due to increased aversion to ethanol.
Some of our most striking findings are the differences in motor activity between the mutants. Consistent with previous results (Sur et al., 2001), β2 null mice demonstrated very high levels of motor activity, and this high basal activity may have prevented ethanol from producing any further enhancement of activity. In contrast, α1 knockout mice were super-sensitive to the stimulant effect of ethanol but displayed a lower level of basal motor activity than did wild-type mice. It is of interest to consider possible signaling systems that might account for the increased ethanol-stimulated motor activity seen in the α1 null mutant mice. For example, activation of GABAA receptor by THIP blocks the motor stimulant effect of ethanol (Broadbent and Harless, 1999). Thus, removal of tonic inhibitory GABAergic tone in the α1 knockout mice may enhance stimulatory effect of ethanol. The distinct effects of deletion of α1or β2 subunits may be related to the selective expression of α subunits in the limbic and basal ganglia systems. For example, dopaminergic neurons of the ventral tegmental area and substantia nigra pars compacta contain α3 and not other α subunits; likewise, the striatum and nucleus accumbens contain α2-4, but not α1 subunits. In contrast, the interneurons in these brain regions contain α1 (and β2) subunits (Schwarzer et al., 2001). This raises the possibility that reduction of GABAergic tone on dopamine neurons (produced by the β2 deletion) is required for the increase in basal activity, but GABAA receptors on interneurons are more important for the stimulatory actions of ethanol. It is of interest to note that a recent publication (Kralic et al., 2002b) found that deletion of the α1 subunit increased the sedative action of diazepam, rather than augmenting the stimulant action. This is consistent with more diverse and complex actions of ethanol in comparison with diazepam.
Deletion of GABAA receptor subunits reduced the consumption of sweet and bitter solutions, and this is consistent with suggestions that activation of GABAA receptors promotes consumption of tastants. For example, benzodiazepines, apart from their anxiolytic actions, also exert effects on the affective appraisal of taste stimuli (reviewed by Berridge and Pecina, 1995). For example, Berridge and Treit (1986), using a taste reactivity method, reported that chlordiazepoxide increased the positive hedonic responses to sweet-, sour-, and bitter-tasting solutions infused into the mouth; the occurrence of aversive affective reactions remained unchanged or was suppressed. These data suggest that reduction of GABAA receptors might reduce positive hedonic responses to different tastants.
In view of the central role of GABAA receptors in suppressing seizure activity in general and alcohol withdrawal convulsions in particular (Buck and Finn, 2001), it is quite surprising that the α1 null mutants do not show greater HIC scores than those for wild-type controls before or after chronic alcohol consumption. The β2 null mutants show some elevation of handling-induced convulsions before chronic ethanol consumption and an increase in seizures upon withdrawal from ethanol, but these effects are not marked. However, the modest increase in withdrawal seizures in the β2 mutants could be influenced by their increased consumption of the ethanol-containing liquid diet at the beginning of the experiment. This raises the important point that in addition to the changes in levels of other GABAA subunits shown by Sur et al. (2001), there are likely changes in other brain proteins in response to deletion of GABAA receptor subunits. Understanding the compensatory mechanisms and other neural strategies that allow these mutant mice to maintain near-normal brain excitability despite the loss of many GABAA receptors should provide new insight regarding genetic regulation of brain function.
In summary, these studies provide support for the importance of GABAA receptors in behavioral actions of ethanol and emphasize that different behavioral actions of ethanol are mediated by distinct GABAA receptors.
Acknowledgments
We thank Drs. Thomas Rosahl and David Reynolds for providing the breeding stocks used for this study and for their comments on the manuscript.
Footnotes
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This work was supported by funds from the Texas Commission on Alcohol and Drug Abuse, and by National Institute on Alcohol Abuse and Alcoholism Integrated Neuroscience Initiative on Alcoholism Consortium and National Institutes of Health Grants AA06399 and AA13520.
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Article, publication date, and citation information can be found at http://jpet.aspetjournals.org.
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DOI: 10.1124/jpet.103.049478.
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ABBREVIATIONS: THIP, 4,5,6,7-tetrahydroisoxazolo[5,4- c]pyridin-3-ol; HIC, handling-induced convulsion; CS, conditioned stimulus; ANOVA, analysis of variance; CTA, conditioned taste aversion.
- Received January 23, 2003.
- Accepted March 4, 2003.
- The American Society for Pharmacology and Experimental Therapeutics