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The Journal of Neuroscience, March 15, 2001, 21(6):2166-2177
GABAA Receptors Containing  5 Subunits in the CA1
and CA3 Hippocampal Fields Regulate Ethanol-Motivated Behaviors: An
Extended Ethanol Reward Circuitry
Harry L.
June1,
Scott
C.
Harvey2,
Katrina L.
Foster1,
Peter F.
McKay1,
Rancia
Cummings1,
Marin
Garcia1,
Dynesha
Mason1,
Collette
Grey1,
Shannan
McCane1,
La Shone
Williams1,
Timothy B.
Johnson1,
Xiaohui
He3,
Stephanie
Rock1, and
James M.
Cook3
1 Psychobiology Program, Department of Psychology,
Indiana University-Purdue University, Indianapolis, Indiana 46202, 2 Laboratory of Neuroscience, Eli Lilly & Company,
Indianapolis, Indiana 46285, and 3 Department of Chemistry,
University of Wisconsin, Milwaukee, Wisconsin 53201
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ABSTRACT |
GABA receptors within the mesolimbic circuitry have been
proposed to play a role in regulating alcohol-seeking behaviors in the
alcohol-preferring (P) rat. However, the precise GABAA
receptor subunit(s) mediating the reinforcing properties of EtOH
remains unknown. We examined the capacity of intrahippocampal infusions of an  5 subunit-selective (~75-fold) benzodiazepine (BDZ) inverse agonist [i.e., RY 023 (RY) (tert-butyl 8-(trimethylsilyl)
acetylene-5,6-dihydro-5-methyl-6-oxo-4H-imidazo [1,5a] [1,4]
benzodiazepine-3-carboxylate)] to alter lever pressing maintained by
concurrent presentation of EtOH (10% v/v) and a saccharin solution
(0.05% w/v). Bilateral (1.5-20 µg) and unilateral (0.01-40
µg) RY dose-dependently reduced EtOH-maintained
responding, with saccharin-maintained responding being reduced only
with the highest doses (e.g., 20 and 40 µg). The competitive BDZ
antagonist ZK 93426 (ZK) (7 µg) reversed the RY-induced suppression
on EtOH-maintained responding, confirming that the effect was mediated
via the BDZ site on the GABAA receptor complex.
Intrahippocampal modulation of the EtOH-maintained responding was
site-specific; no antagonism by RY after intra-accumbens [nucleus
accumbens (NACC)] and intraventral tegmental [ventral
tegmental area (VTA)] infusions was observed. Because the VTA and NACC
contain very high densities of 1 and 2 subunits, respectively, we
determined whether RY exhibited a "negative" or "neutral"
pharmacological profile at recombinant 1 3 2, 232, and
532 receptors expressed in Xenopus oocytes. RY
produced "classic" inverse agonism at all receptor
subtypes; thus, a neutral efficacy was not sufficient to explain the
failure of RY to alter EtOH responding in the NACC or VTA. The results provide the first demonstration that the 5-containing
GABAA receptors in the hippocampus play an important role
in regulating EtOH-seeking behaviors.
Key words:
ethanol; GABA; 5 subunit; reinforcement; hippocampus; alcohol-preferring (P) rat
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INTRODUCTION |
Pharmacological studies support an
involvement of GABAA receptor mechanisms in
regulating EtOH-seeking behaviors (June et al., 1998a ,b; McBride and
Li, 1998). Direct infusion of negative GABAergic modulators [e.g.,
GABAA antagonists and benzodiazepine (BDZ)
inverse agonists] in the extended amygdala and its afferent projection
sites have provided convincing evidence supporting the role for
GABAergic mechanisms in alcohol euphoric properties (Hodge et al.,
1995; June et al., 1998a,b; Koob et al., 1998). However, these
compounds are "nonselective" GABA antagonists and are therefore not
capable of dissecting out potential roles of specific
GABAA receptor subunits in regulating
EtOH-seeking behaviors. Furthermore, the remarkable heterogeneity in
many traditional EtOH reward substrates (Fritschy and Mohler, 1995)
have precluded study of the precise GABAA
subunit(s) mediating EtOH-seeking behavior.
RY 023 (RY) [tert-butyl 8-(trimethylsilyl)
acetylene-5,6-dihydro-5-methyl-6-oxo-4H-imidazo [1,5a] [1,4]
benzodiazepine-3-carboxylate] is one of a series of 8-substituted
imidazobenzodiazepine inverse agonists (Lui et al., 1995, 1996;
Skolnick et al., 1997) developed from the anti-EtOH agent Ro 15-4513
(Suzdak et al., 1986). RY exhibits both high affinity
(Ki of ~2.7
nM) and selectivity (~75-fold) at recombinant
GABAA receptors composed of 522 subunits
(Lui et al., 1996). At recombinant 522 receptors expressed in
Xenopus oocytes, it produces a small reduction in GABA
binding (~25 ± 5%), and its convulsant activity is seen only
with high doses (CD50  40 mg/kg). This
contrasts the efficacy profile common to the nonselective
negative GABAergic modulators [e.g., bicuculline, 2-(3-carboxypropyl)-3-amino-6-(4methoxyphenyl)pyridazinium bromide, and
picrotoxin] (Lui et al., 1995, 1996). Thus, RY represents an
"ideal" pharmacological tool to explore the role of the 5 subunit in the neurobehavioral effects of alcohol.
Although the 5 subunits are minor constituents of the total
GABAA receptor pool, immunocytochemical,
in situ hybridization, and radioligand binding studies show
that the CA1, CA2, and CA3 fields are enriched in this subunit compared
with other brain areas (Wisden et al., 1992; Fritschy and Mohler, 1995;
Sur et al., 1999). The CA1 and CA3 hippocampal fields are particularly interesting candidate sites for the study of alcohol-motivated behaviors because projections from the CA1 and CA3 fields, via the
subiculum, innervate several putative EtOH reward substrates [e.g.,
nucleus accumbens (NACC), amygdala, bed nucleus of the stria
terminalis, hypothalamus, and olfactory tubercle] (Kelley and
Domesick, 1982; Groenewegen et al., 1987; Amaral and Witter, 1995).
We tested the hypothesis that the 5 subunits of the CA1 and CA3
hippocampal fields would regulate EtOH-motivated behaviors in the
alcohol preferring (P) rat. To accomplish this, the actions of
bilateral and unilateral microinjections of RY in the CA1 and CA3
hippocampal fields were evaluated for their capacity to reduce EtOH-maintained responding. The degree of neuroanatomical specificity produced by RY was examined after both bilateral and unilateral control
injections into the NACC and ventral tegmental area (VTA). Unlike the
hippocampal fields, these brain areas possess high levels of 2 and
1 subunit activity, respectively (Wisden et al., 1992; Turner et
al., 1993; Fritschy and Mohler, 1995). The specificity of RY on
consummatory responding was evaluated by determining the effects of RY
in P rats whose response rates for EtOH (10% v/v) and saccharin
solutions (0.05% w/v) were similar at basal levels.
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MATERIALS AND METHODS |
Subjects
Female selectively bred P (n = 83) rats from the
S47 and S48 generations (Lumeng et al., 1995) were ~4-5 months of
age at the beginning of the experiment. During this period, the rats weighed between 195 and 265 gm. No effects of estrous cycle have been
observed on EtOH drinking patterns in female P rats (McKinzie et al.,
1996), and female P rats maintain their body weights within a range
that allows for more accurate stereotaxic placement than male P rats
(Nowak et al., 1998). Animals were individually housed in wire-mesh
stainless steel cages or plastic tubs. The vivarium was maintained at
an ambient temperature of 21°C and was on a normal 12 hr light/dark
cycle. All rats were provided ad libitum access to food and
water, except during the first 2 d of the training phase wherein
rats were fluid-deprived 23 hr daily (see below). Thereafter, rats were
maintained on ad libitum food and water. All training and
experimental sessions took place between 10:00 A.M. and 3:00 P.M. All
procedures were conducted in strict adherence with the NIH Guide
for the Care and Use of Laboratory Animals.
Synthesis of RY 023
Isotoic anhydride was heated with sarcosine in DMSO to provide
the known intermediate 1,4-benzodiazepine. Then the aromatic ring of
this 1,4-benzodiazepine was brominated by bromine in acetic acid in the
presence of sodium acetate to give the 7-bromo-1,4-benzodiazepine in
high yield. Conversion of the 7-bromo-1,4-benzodiazepine into the
8-bromoimidazobenzodiazepine was then accomplished according to the
published work of Gu et al. (1993) and Austin et al. (1981). A Heck
type coupling reaction of this 8-bromoimidazobenzodiazepine was used to
install the trimethylsilyl acetylene functionality at position 8 of the
imidazobenzodiazepine nucleus. The Heck coupling reaction provided RY
in excellent yield.
Other drugs and solutions
EtOH (10% v/v) and saccharin solutions (0.05% w/v) were
prepared for the operant chamber as described previously (June et al.,
1998a,b). The competitive BDZ antagonists ZK 93426 (ZK) (Schering, Berlin, Germany), flumazenil (Ro 15-1788), and the inverse agonist Ro
15-4513 (Hoffman La Roche, Nutley, NJ) were donated as gifts.
Behavioral testing apparatus
Behavioral testing was conducted in 15 standard operant chambers
(Coulbourn Instruments, Allentown, PA) equipped with two removable levers and two dipper fluid delivery systems enclosed in
sound-attenuated cubicles as described previously (June et al.,
1998a-c). All dipper presentations provided a 1.5 sec access to a 0.1 ml dipper, followed by a 3 sec time-out period. Above each lever, three
stimulus lights (red, green, and yellow) were present, and a stimulus
delivery-reinforcer was indicated by illumination of the middle
(green) stimulus light. Responses and reinforcements were recorded and
controlled by 486 IBM computers using the 4.0 Coulburn L2T2 operant
software package.
Behavioral training in the operant chamber
A concurrent fixed-ratio (FR) schedule was used to investigate
the capacity of direct microinjections of RY to selectively reduce EtOH
and saccharin-maintained responding. The specific details of these
procedures have been described recently (June et al., 1998f, 1999). In
brief, rats were initially trained to orally self-administer
EtOH and water in daily 60 min sessions on a concurrent FR1 schedule.
After a period of stabilization on the FR1 schedule, the response
requirement was increased to a concurrent FR4 schedule. After
stabilization on the FR4 schedule, a series of preliminary studies were
conducted to determine the saccharin concentration that produced
response rates and profiles similar to that of EtOH (June et
al., 1998f, 1999). Of the saccharin concentrations tested, the 0.025 and 0.05% w/v concentrations produced response rates and profiles of
responding that were similar to those of EtOH (see below).
Stabilization on the concurrent FR4 schedule for EtOH and the saccharin
concentrations (0.05% or 0.025% w/v) was conducted for 3-4
additional weeks before beginning the drug treatment phase. Responding
was considered stable when responses were within ±20% of the average
responses for 5 consecutive days. The position of the levers and
associated dippers for each reinforcer was alternated on each session
to control for the establishment of lever preference under all
concurrent schedules. The importance of alternative and concurrently
presented reinforcers in examining the positive reinforcing properties
of drugs of abuse has been discussed previously (Carroll et al., 1989;
Heyman and Oldfather, 1992; Meisch and Lemaire, 1993) (for a more
recent discussion, see June et al., 1998f, 1999; Rodefer et al.,
1999).
Experiments 1 and 2 (Microinjection studies)
Assignment to surgical groups. Because only selected
rats, despite extensive training, were capable of lever pressing
concurrently for EtOH (10% v/v) and a saccharin reinforcer at
relatively similar rates of responding, only rats that evidenced
response rates of at least 65-80% of the alternative reinforcer were
selected to evaluate the drug treatments (for more details, see June et
al., 1998f, 1999). Using this criterion, 83 rats were selected to
participate in the study. Of these, 14 rats lever pressed for 10%
(v/v) EtOH and 0.05% (w/v) saccharin at similar rates, whereas the
remaining 69 lever pressed for 10% (v/v) EtOH and 0.025% (w/v)
saccharin at similar rates. Of the 69 rats, 14 were then randomly
assigned to the hippocampal group, 14 to the VTA group and 14 to the
NACC group. These rats were used in experiment 1 for bilateral
implantation. From the remaining 27 rats, nine were randomly assigned
to a second hippocampal group, nine to a second VTA group, and nine to
a second NACC group. These rats were used in experiment 2 for
unilateral implantation. The unilateral study was conducted to
determine whether occupancy of GABAA receptors
containing 5 subunits in a single hemisphere would be sufficient to
produce antagonism of EtOH-maintained responding. Previously, we
reported that unilateral injections in the NACC of nonselective
imidazobenzodiazepines were capable of producing antagonism of
EtOH-motivated responding (June et al., 1998a).
Implantation of guide cannulas. Standard stainless steel
guide cannulas (26 gauge) were stereotaxically implanted
bilaterally and unilaterally in the hippocampus [anteroposterior (AP),
 4.8; mediolateral (ML), ±3.0; dorsoventral (DV) 3.8 (CA1); DV,
4.8 (CA3)], VTA [AP, 5.7; ML, ±1.6; DV, 9.2], and NACC [AP,
+2.0; ML, ±1.4; DV, 7.2]. The coordinates are given in millimeters relative to bregma based on the Paxinos and Watson (1998) atlas. In the
bilateral hippocampal group, seven received implants in the CA1,
whereas the remaining seven received implants in the CA3. In the
unilateral hippocampal group, five rats received implants in the CA1,
whereas the remaining four received implants in the CA3. Rats were
given 7 d to recover from surgery before returning to training in
the operant chamber.
Microinjection procedures. The infusions were delivered
immediately before the operant session with a Harvard infusion pump, during which time animals were able to move about freely in their home
cages. The injection cannula extended 1 mm beyond the tip of the guide
cannulas. When RY was microinjected into a brain locus, it was
dissolved in artificial CSF (aCSF) (composition in
mM: 120 NaCl, 4.8 KCl, 1.2 KH2PO4, 1.2 MgSO4, 25 NaHCO3, 2.5 CaCl2, and 10 D-glucose).
The competitive BDZ antagonist ZK was prepared in a similar manner
whether given alone or in combination with RY (for details, see June et
al., 1998b). When necessary, HCl acid or NaOH was added to the
solutions to adjust pH levels to ~7.4 ± 0.1. RY (0-40 µg) or
aCSF was infused bilaterally for 5 min at a rate of 0.1 µl/1 min
using a 28 gauge injector cannula. The injector cannula was connected
by polyethylene tubing to a 10 µl Hamilton microsyringe. The
injection volume delivered to each hemisphere was 0.5 µl, with a
total injection volume for both the left and right hemispheres of 1 µl. Thus, if a rat received a drug treatment of 20 µg, both the
left and right hemispheres received 10 µg in a volume of 0.5 µl.
Rats receiving unilateral infusions received their drug dose in a total
injection volume of 1 µl. After completion of the 5 min infusion
period, the injector was left in place for an additional 1 min to allow
diffusion from the needle tip. In experiment 1, the competitive,
-carboline BDZ antagonist ZK (7 µg) (see Jensen et al., 1984; Duka
et al., 1987; Duka and Dorow, 1995) was given 5 min before the RY (20 µg). When the combination treatment was given, rats were placed in
the operant boxes immediately after infusion of the RY. The dose range
of RY was selected based on previous research in our laboratory
evaluating the actions of unilateral and bilateral infusions of RY in
selected brain loci (June et al., 1998e; Foster et al., 1999). The 20 µg RY dose was selected for antagonism by the competitive BDZ
antagonist because it produced the greatest reduction of EtOH and
saccharin-maintained responding in both our preliminary work (Foster et
al., 1999) and the present study. The dose of the BDZ antagonist was
selected based on our preliminary work showing it was effective in
antagonizing the EtOH suppression of other imidazobenzodiazepine
inverse agonists (our unpublished data). To control for
carry-over effects, subsequent pretreatments were not administered
until both EtOH and saccharin responding had returned to their predrug
baseline levels for at least 3 d, with a minimum of 3 d
between all drug treatments. All aCSF and drug treatments were
administered in a randomize design in each experiment. Rats received a
maximum of seven bilateral infusions in experiment 1 and six unilateral
infusions in experiment 2.
Histology. After the completion of the behavioral testing,
animals were killed by CO2 inhalation.
Cresyl violet (0.5 µl) was injected into the infusion site, and the
brains were removed and frozen. The frozen brains were sliced on a
microtome at 50 µm sections, and the sections were stained with
cresyl violet acetate. Infusion sites were examined under a light
microscope and indicated on drawings adapted from the rat brain atlas
of Paxinos and Watson (1998). Rats with improper placements were
excluded from the final data analysis.
Blood-alcohol concentration measurement. To ensure that
animals were consuming pharmacologically relevant amounts of EtOH during operant sessions, blood-alcohol concentrations (BACs) were collected in a subset of animals on days animals did not receive drug
treatment. After the first 30 min of an operant session, ~100 µl of
whole blood was collected from the rats' tail tip into a
heparin-coated microsample tube. The BAC samples were collected at the
30 min time point because the majority of EtOH-maintained responding
typically occurred during the first half of the 1 hr operant session
(June et al., 1998a,b). After collection, the whole blood was
immediately centrifuged for 5 min at 1100 rpm. Plasma samples of 5 µl
were collected with a Gilson Medical Electric (Middleton, WI) Microman
M-25 pipette and injected directly into a GL-5 Analyzer (Analox
Instruments, Luxenburg, MA). Microanalysis consisted of measuring the
oxygen consumption in the reaction between the sample of alcohol and
alcohol oxidase using a Clark-type amperometric oxygen electrode.
Alcohol reagent buffer solutions (pH 7.4) and alcohol oxidase enzymes
were used in all samples tested. Results were calculated in units of
milligram per deciliter and printed within 20 sec of each trial.
To ensure accuracy of measurement, each BAC sample was calibrated
twice. The mean of the two samples was used as an index of the level of
BAC content for a given rat. Single-point calibrations were performed
using 5 µl of aqueous 100 mg/dl (21.7mmol/l) standard.
Statistical analysis. All microinjection data were obtained
and analyzed after correct histological verification under a light microscope. The operant-maintained responding data were analyzed by
a single-factor repeated-measures ANOVA with drug treatment (i.e.,
dose) as the independent factor. The dependent variables were EtOH and
saccharin-maintained responding. Each dependent variable was analyzed
separately. Post hoc comparisons between individual drug
treatments were made using the Newman-Keuls test in all experiments.
In general, drug treatment comparisons were made against the aCSF
control condition and the no injection baselines (i.e., BL1 and BL2).
The BL1 condition was the average of 5 d before the animals
received any drug treatment, whereas the BL2 condition was the average
of 5 d after animals received their final drug treatment. The
first day of the BL2 condition was taken 4-5 d after the rats' final
drug treatment. The BL1 and BL2 conditions were included in the design
to evaluate the reliability of our operant training procedures across
the entire duration of the study and to serve as an additional control
condition to compare our aCSF and drug treatment manipulations. When
BL1 and BL2 are depicted in the figures, because the two did not differ
statistically from each other, we will discuss these data as a single
"no injection control condition," albeit both were analyzed in the
original study design. Finally, to determine the time course of
antagonism across the 60 min session, a drug treatment × time
analysis was conducted for the cumulative responses for both EtOH and
saccharin. Correlated t tests were conducted in each
experimental group to compare response rates between EtOH and
saccharin-maintained responding under baseline and aCSF conditions.
Experiment 3 (Xenopus oocyte expression study)
Materials. Xenopus laevis frogs were purchased from
Xenopus-1 (Dexter, MI). Collagenase B was purchased from
Boehringer Mannheim (Indianapolis, IN). GABA was purchased from
Research Biochemicals (Natick, MA). All compounds were prepared at a 10 mM stock solution in ethanol and stored at
20°.
cDNA clones. The rat GABAA receptor
1, 2, 5, and 2 subunit clones were gifts from H. Luddens
(Department of Psychiatry, University of Mainz, Germany). The rat
GABAA receptor 3 subunit clone was a gift from
L. Mahan (National Institute of Neurological Disorders and Stroke,
National Institutes of Health, Bethesda, MD).
Injection of in vitro synthesized RNA into
Xenopus oocytes. Capped cRNA was synthesized from linearized
template cDNA encoding the subunits using mMESSAGE mMACHINE kits
(Ambion, Austin, TX). Oocytes were injected with the , , and subunits in a 1:1:1 molar ratio as determined by UV absorbance.
Mature X. laevis frogs were anesthetized by submersion in
0.1% 3-aminobenzoic acid ethyl ester, and oocytes were surgically removed. Follicle cells were removed by treatment with collagenase B
for 2 hr. Each oocyte was injected with 50-100 ng of cRNA in 50 nl of
water and incubated at 19° C in modified Barth's saline (88 mM NaCl, 1 mM KCl, 2.4 mM NaHCO3, 0.41 mM CaCl2, 0.82 mM MgSO4, 100 µg/ml
gentamicin, and 15 mM HEPES, pH 7.6). Oocytes
were recorded from after 3-10 d after injection.
Electrophysiological recordings. Oocytes were perfused at
room temperature in Warner Instruments (Hamden, CT) oocyte recording chamber #RC-5/18 with perfusion solution (in mM:
115 NaCl, 1.8 CaCl2, 2.5 KCl, and 10 HEPES, pH
7.2) (Harvey et al., 1997). Perfusion solution was gravity fed
continuously at a rate of 15 ml/min. Compounds were diluted in
perfusion solution and applied until after a peak current was reached.
Current responses to GABA application were measured under two-electrode
voltage clamp, at a holding potential of 60 mV. Data were collected
using a GeneClamp 500 amplifier and Axoscope software (Axon
Instruments, Foster City, CA). GABA concentration-response curves for
the GABAA receptor subunit combinations were
constructed by normalizing responses to a low concentration of GABA to
minimize variability and then renormalized to the maximal response for comparison. Concentration-response data were fitted to a
four-parameter logistic using GraphPad Prizm, and the
EC50 for each receptor subtype was determined.
Peak whole-cell current responses of a voltage-clamped oocyte to an
EC50 concentration of GABA in the presence of
saturating (1-10 µM) concentrations of modulators are
reported as a percentage of the peak response to GABA alone ("percent
GABA response" or "% control").
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RESULTS |
Experiment 1: bilateral study
Histologies
Figure 1A-D shows
a reconstruction of serial coronal sections of the rat brain
illustrating the location of the bilateral microinjection cannulas in
the CA1 and CA3 hippocampus (A, B), NACC
(C), and VTA (D). Figures
2A-F and
3A-D show examples of representative photomicrographs for the three groups illustrating the
extent of the lesions sustained as a result of the bilateral guide
cannula. The cannula tracks were well localized in the CA1 or CA3
fields of the hippocampus, NACC, and VTA.
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Figure 1.
Reconstruction of serial coronal sections of the
rat brain illustrating the bilateral guide cannula tips for hippocampal
(n = 9) (A, B),
NACC (n = 9) (C), and
VTA (n = 10) (D) rats
included in the data depicted in Figure 4A-C.
Each rat is represented by two solid black circles: one
in the left and one in the right hemisphere. Coronal sections are
adapted from the rat brain atlas of Paxinos and Watson (1998),
reproduced with permission from Academic Press.
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Figure 2.
Representative histological photomicrographs for
four rats illustrating coronal sections of the CA1 (dorsal) and CA3
(ventral) hippocampus. The photomicrographs depicts the guide cannula
tracks and the magnitude of cellular damage caused by the bilateral
cannula implantation.
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Figure 3.
Representative histological photomicrographs of
coronal sections for the NACC (n = 2)
(A, B) and VTA (n = 2) (C, D) rats. A and
C depict the cellular damage caused by the bilateral
cannula implantation, and B and D show
the effects of the unilateral implantation.
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Control rates of EtOH and saccharin-maintained responding and
BAC levels
Figure
4A-C shows that EtOH
and saccharin-maintained responding within each group were similar in
the bilateral hippocampus, NACC, and VTA groups under the control
conditions (p > 0.05). The BACs (i.e., in
milligrams per deciliter) in the hippocampal rats (24.4-83.37 mg/dl)
(n = 6) correlated significantly with EtOH-maintained
responding and intake (i.e., in grams per kilogram) (r = 0.98, p < 0.01 and r = 0.99, p < 0.0, respectively). The BACs in the VTA rats
(18.6-92.46 mg/dl) (n = 8) were also highly correlated
with EtOH-maintained responding and intake (r = 0.98, p < 0.01 and r = 0.99, p < 0.01, respectively). However, in the NACC rats
(n = 8), the correlations between the BACs (12.6-94.75 mg/dl) and EtOH-maintained responding and intake (r = 0.52, p > 0.10 and r = 0.50, p > 0.23, respectively) did not reach statistical significance.
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Figure 4.
Dose-response of bilateral infusions of RY
(0.0-20 µg) in the hippocampus (n = 9)
(A), NACC (n = 9)
(B), and VTA (n = 10)
(C) on a concurrent fixed-ratio (FR4) schedule
for EtOH (10% v/v) and saccharin-maintained (0.025% w/v)
(SACC) responding. Immediately after the
microinfusions, rats were placed in the operant chamber to lever press
for a 60 min session. *p  0.05 versus the no
injection control conditions (BL1 and BL2) and aCSF control condition
values by ANOVA and post hoc Newman-Keuls test
(n = 9). Error bars represent ±SEM in this
and subsequent figures.  p < 0.01 versus the 20 µg RY alone condition by ANOVA and post
hoc Newman-Keuls test (n = 9). ZK, the
competitive BDZ antagonist, completely reverses the suppression by RY
on EtOH and saccharin-motivated responding. RY was without effect on
EtOH or saccharin-maintained responding in the NACC and VTA (see
Materials and Methods).
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RY drug treatments
Hippocampus. Figure 4A shows rates of
responding maintained by EtOH (top panel) after
microinjection of the 1.5-20 µg doses of RY. RY produced a
dose-related suppression on EtOH-maintained responding. A highly
significant main effect of drug treatment emerged from these data
(F(6,54) = 9.07, p < 0.0001). The Newman-Keuls post hoc tests revealed that all
doses significantly suppressed EtOH responding compared with the aCSF
and baseline conditions (p 0.01). The
bottom panel of Figure 4A shows rates of
responding maintained by saccharin. The 10 µg dose elevated
saccharin-maintained responding, whereas the 20 µg dose produced a
marked suppression on responding (p < 0.01).
These findings yielded a significant main effect of drug treatment
(F(6,54) = 3.36, p < 0.0069).
Cumulative response profiles: time course effects of RY
Figure 4B illustrates the cumulative response
profiles for EtOH under the aCSF, no injection control (e.g., BL and
BL2), and RY treatment conditions. Approximately 45% of the total
EtOH-maintained responding occurred during the initial 10 min of the
operant session, and 88% occurred by the end of the 30 min interval
under the control conditions. All RY doses disrupted the initiation of
responding during the first 10 min of the operant session
(p 0.05) and, thereafter, produced sustained
suppression throughout the remainder of the 60 min session
(p 0.05). A significant drug treatment × time interaction emerged from these data
(F(6,30) = 8.98, p < 0.0001). Figure 4C illustrates the cumulative response
profiles for saccharin. Approximately 36% of the total
saccharin-maintained responding occurred during the initial 10 min
interval, whereas 76% occurred by the end of the 30 min under the
control conditions. The 10 µg dose significantly
elevated saccharin responding throughout the entire 60 min interval
(p 0.05), whereas the 20 µg dose significantly suppressed saccharin-maintained responding throughout the
20-60 min intervals (p 0.05). These data
profiles produced a significant drug treatment × time interaction
(F(6,30) = 3.43, p < 0.001).
Evaluation of the competitive BDZ antagonist (ZK) to
attenuate the RY-induced suppression of EtOH and saccharin-maintained
responding
In Figure 4A the -carboline antagonist ZK (7 µg) and the combination condition (i.e., 7 µg ZK plus 20 µg RY)
were compared with the aCSF and two BL control conditions. ZK was
effective in reversing the attenuation produced by the 20 µg dose of
RY (p < 0.01), and when given alone, it also
suppressed EtOH-maintained responding (p < 0.01). These data profiles yielded a significant main effect of drug
treatment (F(4,36) = 6.401, p < 0.0005). The bottom panel of Figure
4A depicts the actions of ZK alone (7 µg) and in
combination with the 20 µg dose of RY on saccharin-maintained responding. These data show that ZK also attenuated the RY-induced suppression on saccharin-maintained responding
(p < 0.05). However, given alone, ZK did not
alter saccharin-maintained responding (p > 0.05).
Neuroanatomical control sites: NACC and VTA
Figure 5A shows rates of
responding maintained by EtOH (top panel) and
saccharin (bottom panel) after microinjection of the 0.5-20 µg doses of RY into the NACC. Compared with the aCSF and BL
control conditions, none of the RY treatments altered EtOH or
saccharin-maintained responding
(F(7,56) = 0.737, p > 0.05 and F(7,56) = 0.805, p > 0.05, respectively). A similar profile of effects
were observed in the VTA for EtOH and saccharin-maintained responding
(F(5,45) = 0.215, p > 0.05 and F(5,45) = 0.907, p > 0.05, respectively).
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Figure 5.
Cumulative time course profile across the 60 min
interval for EtOH (A) and saccharin-maintained
(B) responding relative to the control conditions
[i.e., aCSF and no injection control (e.g., BL and BL2)]. All RY
doses disrupted the initiation of responding during the first 10 min of
the operant session and, thereafter, produced sustained suppression
throughout the remainder of the 60 min session
(p 0.05). RY was without effect on
saccharin-maintained responding during the initial 10 min for the 1.5, 5, and 20 µg doses (p > 0.05); however,
beginning at the 20 min interval and throughout the remainder of the 60 min session, the 20 µg dose produced a profound suppression on
responding (p 0.05). In contrast, the 10 µg dose significantly elevated saccharin responding across the entire
60 min session (p < 0.05).
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Experiment 2: unilateral study
Histologies
Figure 6A-C shows
a reconstruction of serial coronal sections of the rat brain
illustrating the location of the unilateral microinjection cannulas in
the CA1 and CA3 hippocampus (A), NACC (B), and VTA (C). Representative
photomicrographs are depicted in Figures 2 and 3.
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Figure 6.
Reconstruction of serial coronal sections of the
rat brain illustrating the unilateral guide cannula tips for
hippocampal (n = 7) (A), NACC
(n = 5) (B), and VTA
(n = 5) (C) rats included in
the data depicted in Figure 7A-C. Each rat is
represented by one solid black circle: one in the left
or in the right hemisphere. Coronal sections are adapted from the rat
brain atlas of Paxinos and Watson (1998), reproduced with permission
from Academic Press.
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Control rates of EtOH and saccharin-maintained responding and
blood EtOH concentration levels
Figures 7A-C shows that
EtOH and saccharin-maintained responding were similar in the
hippocampal and VTA groups (p > 0.05); however,
the NACC group responded significantly higher for the saccharin
reinforcer (p < 0.05). The BACs in the
hippocampal rats (n = 7) correlated significantly with
EtOH-maintained responding and intake (r = 0.95, p < 0.01 and r = 0.95, p < 0.0, respectively). The BACs in the NACC
(n = 5) and VTA (n = 5) rats were also
correlated with EtOH-maintained responding and intake
(r = 0.77, p < 0.05 and
r = 0.79, p < 0.05; r = 0.71, p < 0.05 and r = 0.75, p < 0.05, respectively).
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Figure 7.
Dose-response of unilateral infusions of RY
(0.0-40 µg) in the hippocampus (n = 7)
(A), NACC (n = 5)
(B), and VTA (n = 5)
(C) on a concurrent fixed-ratio (FR4) schedule
for EtOH (10% v/v) and saccharin-maintained (0.025% w/v)
(SACC) responding. Immediately after the microinfusions,
rats were placed in the operant chamber to lever press for a 60 min
session. *p 0.05 versus the aCSF control
condition values by ANOVA and post hoc Newman-Keuls
test. Again, RY failed to alter EtOH or saccharin-maintained responding
in the NACC and VTA.
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RY drug treatments
Hippocampus. Figure 7A (top
panel) shows that unilateral microinjection of RY produced
a clear dose-dependent suppression on EtOH-maintained responding,
yielding a highly significant main effect of drug treatment
(F(5,30) = 42.28, p < 0.0001). Compared with the aCSF control condition, responding was
reduced by 36-86% with the 1-40 µg doses (p < 0.01). The bottom panel of Figure 7A shows
that only the 40 µg dose nonselectively suppressed responding maintained by saccharin (p < 0.01). This
finding yielded a significant main effect of drug treatment
(F(5,30) = 4.91, p < 0.0002).
Neuroanatomical control sites: NACC and VTA
Figure 7, B and C, shows rates of responding
maintained by EtOH (top panel) and saccharin
(bottom panel) after unilateral microinjection of the
0.01-20 µg doses of RY into the NACC and VTA, respectively. Compared
with the aCSF control condition, none of the RY treatments altered EtOH
or saccharin-maintained responding in the NACC
(F(4,16) = 0.394, p > 0.05 and F(4,16) = 1.56, p > 0.05) or VTA
(F(4,16) = 0.779, p > 0.05 and F(4,16) = 0.770, p > 0.05, respectively).
Experiment 3: Xenopus oocyte expression study
Because efficacy is defined by subunit composition (von
Blankenfeld et al., 1990; Wong and Skolnick, 1992; Graham et al., 1996)
and the VTA, NACC, and hippocampus contain high levels of the 1,
2, and 5 subunits, respectively, (Wisden et al., 1992; Duncan et al., 1995; Fritschy and Mohler, 1995; Charlton et al., 1997),
we determined whether the failure of RY to reduce EtOH-maintained responding in the VTA and NACC was attributable to it exhibiting a "different" modulation at the 1 and 2 receptor subtypes
than the 5 receptor. To determine this, the efficacy of RY was
examined at recombinant GABAA receptors composed
of 132, 232, and 532 subunits expressed in
Xenopus oocytes. The anti-alcohol compound Ro 15-4513
(Suzdak et al., 1986) and several "neutral" competitive BDZ
antagonists (e.g., flumazenil and ZK) were used as reference compounds.
The Xenopus system is a useful tool for functional
determination of the efficacy of GABAergic modulators (Puia et al.,
1991).
Activities of GABA modulators at recombinant
GABAA receptors
Receptors containing different GABAA subunits (1, 2, and 5) were coexpressed with both the 3 and
2 subunits. To accurately compare modulator activity between
receptor subtypes, we used an equi-effective
(EC50) concentration of GABA for each
GABAA receptor subtype: 50 µM for
132 and 232, and 30 µM for
532. All modulators were examined at saturating
concentrations, either 1 or 10 µM.
Figure 8A shows that RY
acted as a negative modulator at the 1, 2, and 5 receptor
subtypes, inhibiting GABA-evoked current responses of voltage-clamped
Xenopus oocytes by ~40-55%. The relative magnitude of
GABA inhibition at the 5 and 1 receptors is also depicted by the
current traces illustrated in Figure 9,
A and D. For comparison, the activity of the
nonselective BDZ-positive modulator flunitrazepam is illustrated at
both receptor subtypes in Figure 9, C and F. In
contrast, flunitrazepam produced a 50% potentiation of GABA-evoked
currents at the 5 and 1 receptor subtypes (155 ± 5 and
163 ± 7%, respectively).
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Figure 8.
A-D, Actions of GABAA
receptor modulators on recombinant receptor subtypes. Modulation of
GABAA 132 (white bar), 232
(hatched bar), and 532 (black
bar) receptors by RY (A), ZK
(B), Ro 15-4513 (C), and
Ro 15-1788 (D). Saturating concentrations (1-10
µM) of modulator was coapplied over voltage-clamped
oocytes along with an EC50 of GABA, and the whole-cell
current response in the presence of modulator is reported as a
percentage of the current response to GABA alone (percent GABA
response, mean ± SD of 3-4 separate oocytes except for ZK on
632, which is 7 separate oocytes).
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Figure 9.
A-F, Actions of RY, ZK, and
flunitrazepam on recombinant GABAA receptor subtypes
illustrated by current traces. Top, Current responses of
voltage-clamped oocytes expressing GABAA 532
receptors. A, During application of 30 µM
(EC50) GABA alone for duration indicated by
black bar (left trace). Current response
from the same oocyte subsequently coapplied with 30 µM
GABA along with 10 µM RY for duration indicated by
gray bar (right trace). B,
Current response of a voltage-clamped oocyte during application of 30 µM GABA for duration indicated by black
bar (left trace). Current response from same
oocyte subsequently coapplied with 30 µM GABA along with
10 µM ZK for duration indicated by gray
bar (right trace). C, Current
response of a voltage-clamped oocyte during application of 30 µM GABA for duration indicated by black
bar (left trace). Current response from same
oocyte subsequently coapplied with 30 µM GABA along with
1 µM flunitrazepam (FNP) for duration
indicated by gray bar (right trace).
Bottom, Current responses of voltage-clamped oocytes
expressing GABAA 132 receptors. D,
During application of 50 µM (EC50)
GABA for duration indicated by black bar (left
trace). Current response from same oocyte subsequently
coapplied with 50 µM GABA along with 10 µM
RY for duration indicated by gray bar (right
trace). E, Current response of a voltage-clamped
oocyte during application of 50 µM GABA for duration
indicated by black bar (left trace).
Current response from same oocyte subsequently coapplied with 50 µM GABA along with 10 µM ZK for duration
indicated by gray bar (right trace).
F, Current response of a voltage-clamped oocyte during
application of 50 µM GABA for duration indicated by
black bar (left trace). Current response
from same oocyte subsequently coapplied with 50 µM GABA
along with 1 µM flunitrazepam (FNP) for
duration indicated by gray bar (right
trace). Calibration: A, 10 nA, 10 sec;
B-F, 25 nA, 10 sec.
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The efficacy of the imidazobenzodiazepines Ro 15-4513 and Ro 15-1788
(flumazenil) were also examined at the 132, 232, and
532 receptors (Fig. 8C,D). These parent
compounds were selected because we were interested in evaluating the
degree to which modification at position 8 (which produced the 5
selectivity) (Lui et al., 1995, 1996) would change the capacity of
imidazobenzodiazepine to modulate GABA at specific receptor
subtypes. Ro 15-4513 was also selected because we were interested in
comparing the intrinsic activity of a reference alcohol antagonist
(Suzdak et al., 1986; Harris and Lal, 1988; Jackson and Nutt, 1995)
with RY 023. It should be noted that the capacity of Ro 15-4513 and
flumazenil to produce intrinsic effects at many of the
GABAA-containing subunits are not known. As shown
in Figure 8C, Ro 15-4513 produced a very modest inhibition
of GABA current at the 1 and 2 subtypes (86 ± 3 and 93 ± 1% control response, respectively) but exhibited no efficacy at the
5 receptor (99.5 ± 4.1% control response). Figure
8D depicts the efficacy of the competitive antagonist
flumazenil (Ro15-1788) (Haefely, 1983, 1985, 1990). Ro 15-1788 acted
as a modest positive modulator at the 2 subtype (115 ± 4%
control response) and exhibited no efficacy at either the 1 or 5
subtypes. In contrast, Figure 8B shows that ZK, the
competitive -carboline antagonist (Jensen et al., 1984; Duka et al.,
1987; Duka and Dorow, 1995), acted as a positive modulator
potentiating GABA-evoked current responses at 1- and 2-containing
receptors (146 ± 11 and 140 ± 13% of control,
respectively); however, ZK had no efficacy at the 5 receptor subtype
(95 ± 6% of control). As illustrated in Figure 9, E
and F, the relative magnitude of GABA potentiation by ZK was
comparable with that of the full BDZ agonist flunitrazepam at the 1 receptor.
| |
DISCUSSION |
Microinjection studies
The results of the present study support the hypothesis that
GABAA receptors containing 5 subunits in the
CA1 and CA3 hippocampal fields play an important role in regulating
EtOH-seeking behaviors in the genetically selected P rat. The
intrahippocampal modulation of EtOH-maintained responding was
site-specific; no antagonism by RY was observed after intra-NACC and
intra-VTA infusions (i.e., two brain areas reported to play a
significant role in regulating alcohol-motivated behaviors) (Koob and
Bloom, 1988; Koob et al., 1998; McBride and Li, 1998). The reliability
of the dose-effect analyses was confirmed by correspondence between
the bilateral and unilateral infusions. It is possible that fewer
GABAA receptors containing 5 subunits were
occupied after unilateral infusions; thus, a higher dose was required
to observe the same magnitude of antagonism seen after the bilateral infusions.
The GABA-BDZ systems have been implicated in the regulation of
consummatory behavioral processes (Higgs and Cooper, 1995). However, RY
produced a differential sensitivity in suppressing EtOH compared with
saccharin-motivated responding. Specifically, unilateral and bilateral
infusions were more effective in suppressing EtOH compared with
saccharin-maintained responding (Figs. 4A, 7A). These results are consistent with our systemic studies
wherein EtOH and saccharin response rates were equally matched at basal levels (Foster et al., 1999; June et al., 1999). The nonselective suppression seen by RY with the higher doses is likely attributable to
occupancy of multiple subtype receptors. Hence, the results suggest
that it is unlikely that the RY-induced suppression of EtOH responding
was attributable to a general suppression on consummatory behaviors.
The bilateral and unilateral neuroanatomical control data revealed that
RY infusions produced little effects on EtOH or saccharin-maintained responding in the NACC and VTA. These findings suggest that (1) these brain loci are devoid of 5 receptors or (2) the paucity of
5 receptors in these brain loci are not sufficient to regulate EtOH
and saccharin-maintained responding. However, it should be noted that
infusion of nonselective BDZ inverse agonists in the NACC and VTA have
been reported to produce suppression on EtOH responding (June et al.,
1998a,c). Thus, the NACC and VTA do, in fact, regulate EtOH responding
via GABAergic mechanisms, possibly via other receptor subtypes.
ZK, the competitive BDZ antagonist, reversed the antagonism
produced by RY on both EtOH and saccharin-maintained responding. Hence,
the suppression by RY appears to be mediated via an action at the BDZ
component of the GABA complex. Given alone, ZK also produced a marked
reduction on EtOH responding; however, it did not alter saccharin
responding. That a low dose (7 µg) of ZK was capable of producing
suppression on EtOH responding in the hippocampus [despite its low
affinity at the 5 receptor; IC50 of ~170
nM (I. Pribilla and M. Hillmann, personal communication,
Schering, Berlin, Germany)] suggests that blockade of multiple receptor subtypes (e.g., 15) may be responsible for its
suppression on EtOH-maintained responding. Nevertheless, these findings
are in agreement with our previous research with systemic and oral administration of ZK (June et al., 1996, 1998b,d).
The 5 receptors within the hippocampus may reduce
EtOH-maintained responding by interfering with conditioned stimuli
BDZs have long been proposed to modulate learning and memory
processes via the hippocampus (Izquierdo and Medina, 1991). GABAergic mechanisms in the hippocampus also appear to mediate associations between conditioned and unconditioned stimuli (Phillips and LeDoux, 1992). Samson and Hodge (1996) proposed that response latency (i.e.,
the delay from the beginning of alcohol availability to the onset of
responding) is an index of "initial appetitive processes" and that
conditioned stimuli may play a role in initiating the onset of
lever-press responding. Hence, decrements, or elevations in response
latency, may be indicative of appetitive brain mechanisms. Samson and
Hodge (1996) further proposed that conditioned stimuli during the
"early maintenance phase" (i.e., 15-20 into the operant session)
may also be paired with the CNS pharmacological effects of alcohol on
previous consummatory occasions. Thus, both conditioned reinforcers and
the CNS pharmacological effects of alcohol may reinforce
EtOH-maintained responding. If the 5 receptors within the CA1 and
CA3 hippocampal fields were functionally involved in regulating
conditioned and unconditioned stimuli during the early phases of
EtOH-maintained responding, it can be hypothesized that RY might reduce
EtOH responding by interfering with-reducing conditioned cues that
would normally be present during the operant session to sustain EtOH
responding. It should be recalled that RY produced profound reductions
on the onset of alcohol drinking and led to early termination of
responding (Fig. 4B). Thus, blockade of the CNS
pharmacological effects alone by EtOH may not fully explain the
mechanisms by which RY reduces EtOH-seeking behaviors.
More recently, the hippocampus, and afferents to the hippocampus, have
been proposed to play a role in the cognitive aspects of anxiety
(Crestani et al., 1999; McNaughton, 1999). Thus, the reduction in
alcohol drinking by RY may be related to a reduction in anxiety
attributable to the ability of RY to function as an agonist at the
3, 4, and 6 subunits. Previous reports reveal that negative
BDZ modulators can exhibit agonist effects at some receptor subtypes
(Wong and Skolnick, 1992; Wafford et al., 1993). However, this does not
seem likely because recent work in our laboratory has shown that RY
also exhibits a classic inverse agonist profile at the 3, 4, and
6 receptor subtypes (Foster et al., 1999).
The 5 receptors within the hippocampus may interact with
mesolimbic dopamine systems
Another possible mechanism by which RY reduces EtOH-seeking
behaviors is that blockade of the 5 subtype receptors initiates tonic inhibition of dopamine (DA) neurons at the hippocampal level. RY
may "mimic" the actions of EtOH on the DA system. Because the DA
release induced by RY would replace-substitute the DA normally produced by EtOH responding, less alcohol would subsequently be ingested in the presence of RY (McBride and Li, 1998; Nowak et al.,
1998). Systemic administration of BDZ inverse agonists have been shown
to increase DA and its metabolites in subcortical and cortical areas
(Scheel-Kruger, 1986; Giorgi et al., 1988; Bradberry et al., 1991;
McCullough and Salamone, 1992) (for review, see Bruno and Miller,
1995). A related hypothesis may explain the capacity of ZK to attenuate
EtOH-maintained responding. It should be recalled that, at the 1 and
2 receptor subtypes, ZK exhibited full agonist effects (Figs.
8B, 9E).
Subunit selectivity versus intrinsic activity
Previously, we reported that rank order potencies of BDZs to
attenuate EtOH intake were not correlated with rank order potencies of
BDZs to inhibit GABA
36Cl
conductance and enhance
35S-t-butylbicyclophosphorothionate (TBPS)
binding (June et al., 1995). Whereas the
36Cl flux
and TBPS binding assays use heterogenous subunit populations, with the
resulting value obtained representing an "average efficacy," the
Xenopus oocyte system permits efficacy to be determined at any different subunit-cDNA combinations (Pritchett et al., 1989; Wafford et al., 1993).
In the present study, at saturating concentrations, Ro 15-4513 was
essentially neutral at the 2 and 5 receptors and slightly negative at the 1 receptor. These data are in agreement with previous oocyte studies (Wafford et al., 1993; June et al., 1998g) and
work by Wong and Skolnick (1992) using the GABA shift assay. However,
the findings with Ro 15-4513 contrast those with RY and ZK, in which
the GABA-evoked current is negatively and positively modulated,
respectively, at the 1 and 2 receptor subtypes. Nevertheless, despite the three different intrinsic activity profiles, each ligand is
highly effective in attenuating EtOH-motivated behaviors (Rassnick et
al., 1993; June et al., 1994, 1995a, 1998a,b). Thus, although both
efficacy and subunit selectivity may interact to effectively alter
EtOH-motivated behaviors, subunit selectivity may be the critical
factor in determining the capacity of a ligand to function as an
effective alcohol antagonist. Several investigators suggest that
efficacy is not only dependent on subunit composition but is actually
defined by it (von Blankenfeld et al., 1990; Wong and Skolnick, 1992;
Graham et al., 1996; Skolnick et al., 1997). Thus, efficacy may have
little meaning without subunit selectivity (P. Skolnick, personal communication).
Summary
These findings provide the first demonstration that
GABAA receptor-containing 5 subunits in the
hippocampus play a critical role in regulating some aspects of alcohol
seeking behavior. The precise GABA-hippocampal pathway(s) in which RY
attenuates EtOH reinforcement is not known; however,
GABAA-BDZ neuroanatomical circuits within the
hippocampus may initiate activation of underlying DA substrates in the
mesoaccumbens circuitry to contribute to the reinforcing properties of
EtOH. The functional role of conditioning stimuli in the onset and
maintenance phases of alcohol drinking may also be important.
Nevertheless, we propose that the GABA-hippocampal pathway may
represent an "extension" of the mesolimbic EtOH reward circuitry
and may be an important target in the development of potential
pharmacotherapies for alcohol addiction and dependence. The
Xenopus oocyte studies demonstrated that the capacity of
BDZs to attenuate EtOH-motivated responding was not directly related to
their intrinsic efficacy; rather, their selectivity and differential potency to attenuate EtOH-seeking behaviors appear to be more related
to their affinity and selectivity at different
GABAA-containing receptor subunits.
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FOOTNOTES |
Received June 27, 2000; revised Jan. 4, 2001; accepted Jan. 4, 2001.
This research was supported in part by National Institute of Alcohol
Abuse and Alcoholism Grants AA10406 and AA11555 (H.L.J.) and National
Institute of Mental Health/National Institutes of Health Grant MH 46851 (J.M.C.). K.L.F. and M.G. were supported in part by National Heart,
Lung, and Blood Institute/National Institutes of Health Grant T35M
(Short-Term Training Program for Minority Students in Biomedical
Research). K.L.F. was also supported in part by a Minority Neuroscience
Fellowship from the American Psychological Association. We thank Dr.
Phil Skolnick (Eli Lilly & Co., Indianapolis, IN) for his outstanding
consulting work throughout the duration of this project and for
obtaining the cDNA clones from Drs. Luddens (University of Mainz,
Mainz, Germany) and Mahan (National Institutes of Mental Health). We
also thank Dr. T.-K. Li and the Alcohol Research Center (Indiana
University School of Medicine) for supplying the P rats.
Correspondence should be addressed to Dr. Harry L. June, Department of
Psychology, LD 124, Indiana University-Purdue University, 402 North Blackford Street, Indianapolis, IN 46202-3275. E-mail: hjune{at}iupui.edu.
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ABSTRACT
INTRODUCTION
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