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The Journal of Neuroscience, March 15, 2002, 22(6):2074-2082
Long-Lasting Potentiation of GABAergic Synapses in Dopamine
Neurons after a Single In Vivo Ethanol Exposure
Miriam
Melis,
Rosana
Camarini,
Mark A.
Ungless, and
Antonello
Bonci
Ernest Gallo Clinic and Research Center, Department of Neurology,
University of California, San Francisco, California 94110
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ABSTRACT |
The mesolimbic dopamine (DA) system originating in the ventral
tegmental area (VTA) is involved in many drug-related behaviors, including ethanol self-administration. In particular, VTA activity regulating ethanol consummatory behavior appears to be modulated through GABAA receptors. Previous exposure to ethanol
enhances ethanol self-administration, but the mechanisms underlying
this phenomenon are not well understood. In this study, we examined changes occurring at GABA synapses onto VTA DA neurons after a single
in vivo exposure to ethanol. We observed that evoked
GABAA IPSCs in DA neurons of ethanol-treated animals
exhibited paired-pulse depression (PPD) compared with saline-treated
animals, which exhibited paired-pulse facilitation (PPF). Furthermore,
PPD was still present 1 week after the single exposure to ethanol. An
increase in frequency of spontaneous miniature GABAA IPSCs
(mIPSCs) was also observed in the ethanol-treated animals.
Additionally, the GABAB receptor antagonist
(3-aminopropyl)(diethoxymethyl) phosphinic acid shifted PPD
to PPF, indicating that presynaptic GABAB receptor
activation, likely attributable to GABA spillover, might play a role in
mediating PPD in the ethanol-treated mice. The activation of adenylyl
cyclase by forskolin increased the amplitude of GABAA IPSCs
and the frequency of mIPSCs in the saline- but not in the
ethanol-treated animals. Conversely, the protein kinase A (PKA)
inhibitor
N-[z-(p-bromocinnamylamino)ethyl]-5-isoquinolinesulfonamide significantly decreased both the frequency of spontaneous mIPSCs and
the amplitude of GABAA IPSCs in the ethanol-treated mice
but not in the saline controls. The present results indicate that potentiation of GABAergic synapses, via a PKA-dependent mechanism, occurs in the VTA after a single in vivo exposure to
ethanol, and such potentiation might be a key synaptic modification
underlying increased ethanol intake.
Key words:
ventral tegmental area; ethanol; probability of GABA
release; presynaptic plasticity; cAMP; PKA
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INTRODUCTION |
The mesolimbic dopamine (DA) system
originates in the ventral tegmental area (VTA), and it projects to
structures associated with the limbic system, primarily the nucleus
accumbens (NAcc), the amygdala, the hippocampus, and the prefrontal
cortex (Fuxe et al., 1974 ; Oades and Halliday, 1987). A growing body of
evidence implicates the mesolimbic DA system in the regulation of
ethanol self-administration (Rassnick et al., 1993a; Samson et al.,
1993; Ng and George, 1994; Koob et al., 1998; McBride et al., 1999; Kaczmarek and Kiefer, 2000; Nowak et al., 2000). An important role of
DA in ethanol reinforcement has been suggested by studies showing that
DA receptor antagonists, injected systemically or directly into the
terminal regions of the mesolimbic DA system, decrease lever pressing
for ethanol (Samson et al., 1993; Ng and George, 1994). Furthermore, a
variety of pharmacological manipulations within this pathway, affecting
the activity of DA neurons, produced changes in ethanol consumption,
suggesting that DA neuronal activity within the VTA may be important
for maintaining ethanol consummatory behavior (Rassnick et al., 1993a;
Ng and George, 1994; Kaczmarek and Kiefer, 2000; Nowak et al., 2000).
In fact, a marked reduction of the spontaneous activity of mesolimbic
DA neurons (Diana et al., 1993; Bailey et al., 1998), resulting in
decreased extracellular DA levels in NAcc (Diana et al., 1993), has
been observed during acute withdrawal from chronic ethanol. Moreover,
the fact that ethanol intake in dependent rats greatly exceeds that of
nondependent rats during acute withdrawal, and that increased
self-administration restores DA levels to normal in NAcc, suggests that
decreased DA levels may trigger ethanol-seeking behavior (Weiss et al., 1996). The above-mentioned studies indicate that changes in activity of
VTA DA cells, correlated with extracellular DA levels in the NAcc,
might regulate ethanol consumption (McBride et al., 1995; Weiss et al.,
1996; Hodge et al., 1997; Ikemoto et al., 1997), and accordingly, DA
antagonists impair alcohol self-administration. In the midbrain
dopamine systems, GABAergic neurons exert an inhibitory control on DA
neurons (Johnson and North, 1992b; Hausser and Yung, 1994; Paladini et
al., 1999). Therefore, hyperactivity of VTA GABA cells observed during
acute withdrawal from chronic ethanol (Gallegos et al., 1999) could
account, at least in part, for the reduced DAergic activity. Because
the hypofunction of the DAergic system outlasts the somatic signs of
acute withdrawal (Diana et al., 1996), such an increase of GABAergic
synaptic transmission might not only represent a functional correlate
of acute withdrawal from ethanol but also play a role in both short-
and long-term consequences produced by ethanol exposure.
Interestingly, the influence of the initial exposure to ethanol and the
patterns of its subsequent consumption have been observed in both
humans and laboratory animals (Haertzen et al., 1983; Camarini et al.,
2000; Files et al., 2000). Unfortunately, the relationship between the
reinforcing quality of the first experience and subsequent habits of
ethanol consumption is still unclear. Whether this change in behavior
is attributable to a reduced sensitivity to the stimulant effects of
ethanol (Phillips et al., 1995) or a blockade of the development of
ethanol-induced conditioned taste aversion (Risinger and Cunningham,
1995) remains to be elucidated. Because both systemic and intra-VTA
administration of GABAA receptor agonists
facilitate, whereas antagonists decrease, the acquisition of voluntary
ethanol drinking in rats (Smith et al., 1992; Nowak et al., 1998), the
GABAergic transmission within the VTA might play an important role.
Although the acute effects of ethanol in the mesolimbic system have
been studied extensively (Brodie et al., 1990, 1999; Nie et al., 1993,
1994; Brodie and Appel, 1998, 2000; Steffensen et al., 2000), there are
no studies directly examining whether synaptic changes occur in the VTA
after exposure to ethanol.
To address this issue, we studied GABAA-mediated
IPSCs in VTA DA neurons 24 hr after a single injection of either
ethanol (2 gm/kg, i.p.) or saline.
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MATERIALS AND METHODS |
Slice preparation. The preparation of VTA slices was
as described previously (Thomas et al., 2000). Briefly, C57BL/6J mice (21-35 d; Charles River, Hollister, CA) were anesthetized with halothane and killed. A block of tissue containing the midbrain was
sliced in the horizontal plane (230 µm) with a vibratome (Leica, Nussloch, Germany) in ice-cold low-Ca2+
solution containing (in mM): 126 NaCl, 1.6 KCl, 1.2 NaH2PO4, 1.2 MgCl, 0.625 CaCl2, 18 NaHCO3, and 11 glucose. Slices (two per animal) were transferred in a holding chamber
with a bicarbonate-buffered solution (32-34°C) saturated with
95%O2 and 5%CO2
containing (in mM): 126 NaCl, 1.6 KCl, 1.2 NaH2PO4, 1.2 MgCl2, 2.4 CaCl2, 18 NaHCO3, and 11 glucose. Slices were allowed to
recover for at least 1 hr before being placed in the recording chamber
and superfused with the bicarbonate-buffered solution (32-34°C)
saturated with 95%O2 and
5%CO2.
Whole-cell recording. Only one cell for each experimental
procedure was recorded per mouse. Cells were visualized with an upright
microscope with infrared illumination, and whole-cell voltage-clamp
recordings were made by using an Axopatch 1D amplifier (Axon
Instruments, Foster City, CA). All GABAA IPSC
recordings were made with electrodes filled with an internal solution
containing the following (in mM): 144 KCl, 1 CaCl2, 3.45 K4BAPTA, 10 HEPES, 2 Mg2ATP, and 0.25 Mg2GTP, pH 7.2-7.4. Experiments were begun only
after series resistance had stabilized (typically 15-40 M ). Series
and input resistance were monitored continuously on-line with a 4 mV
depolarizing step (25 msec). Data were filtered at 2 kHz, digitized at
10 kHz, and collected on-line with acquisition software (Igor Pro, Lake
Oswego, OR). Because of the composition of the internal solution, the
GABAA IPSCs were inward at a membrane potential
of  70 mV and were completely blocked by picrotoxin (100 µM). DA cells were identified by the presence of a large Ih current (Johnson and North,
1992a) that was assayed immediately after break-in, using a series of
incremental 10 mV hyperpolarizing steps from a holding potential of
70 mV. A bipolar stainless steel stimulating electrode was placed 100 µm rostral to the recording electrode and was used to stimulate at a
frequency of 0.1 Hz. Neurons were voltage-clamped at a membrane
potential of 70 mV. All GABAA IPSCs were
recorded in the presence of 2-amino-5-phosphonopentanoic acid (AP5; 100 µM), 6-cyano-2,3-dihydroxy-7-nitro-quinoxaline (10 µM), strychnine (1 µM), and eticlopride (100 nM) to block NMDA, AMPA, glycine, and dopamine
D2-mediated synaptic currents, respectively. As described previously
(Bonci and Williams, 1997), this solution had no effect on the holding
current of the dopamine cells. The amplitudes of IPSCs were calculated
by taking a 1 msec window around the peak of the IPSC and comparing
this with the 5 msec window immediately before the stimulation
artifact. Paired stimuli were given with an interstimulus interval of
50 msec, and the ratio between the second and the first IPSCs was
calculated and averaged for a 10 min baseline. Drugs were applied in
known concentrations to the superfusion medium. The spontaneous
miniature IPSCs (mIPSC) were collected in the presence of lidocaine
(500 µM) and analyzed (120 sweeps for each
condition, 1 sec/sweep) using Mini Analysis program (Synaptosoft). To
accurately determine the mIPSC amplitude, only mIPSCs that were >8 pA
were accepted for analysis. The choice of this cutoff amplitude for
acceptance of mIPSCs was made to obtain a high signal-to-noise ratio.
Alcohol self-administration. Sixteen C57BL/6J mice (Charles
River Laboratories, Wilmington, MA) were housed individually in polycarbonate cages, with food and water available ad
libitum, and habituated to their home cage for 1 week before the
experiment. The colony room was maintained on a 12 hr light/dark cycle
with lights on at 6 A.M. All experimental procedures were conducted under institutional and National Institutes of Health guidelines. Oral
ethanol self-administration was examined using a two-bottle choice
protocol (Phillips et al., 1998; Hodge et al., 1999). Mice were offered
the choice between 2% (v/v) ethanol versus water for 5 d. The
ethanol concentration was increased to 5%, and the ethanol consumption
was measured for 5 more days. Fluid volumes consumed were recorded
every day, and the bottle positions were alternated daily. Each day,
the mice were weighed, and then the ethanol consumption was calculated
as grams of ethanol per kilogram.
Blood alcohol determination. Blood tail collection of 3- to
4-week-old mice did not provide enough volume for measurement; therefore, blood ethanol concentration was measured by drawing a 40 µl blood sample from the trunk. Twenty-four hours after either ethanol (2 gm/kg, i.p.) or saline exposure, blood samples were collected at 10, 30, 60, and 90 min after an intraperitoneal 4 gm/kg
injection of ethanol (four or five mice were used for each group and
for every time point). Blood plasma was extracted with trichloroacetic
acid, and plasma ethanol content was measured using a 332 alcohol
diagnostic kit (Sigma, St. Louis, MO).
Results in the text and figures are presented as the mean ± SEM.
Results between groups were compared using a t test, either paired or unpaired where appropriate; p < 0.05 was
taken as indicating statistical significance.
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RESULTS |
In the present study, we investigated the properties of
GABAA IPSCs recorded in VTA DA cells from mice
that received a single in vivo injection of ethanol (2 gm/kg, i.p.) or saline the day before the recordings.
First, to determine whether changes in the probability of GABA release
occurred at these synapses in ethanol-treated mice, we use the
paired-pulse stimulation protocol to test for changes in synaptic
strength elicited by paired stimuli given at an interval of 50 msec. It
has been shown that changes in transmitter release would generally
affect the paired pulse ratio (Khazipov et al., 1995, Mennerick and
Zorumski, 1995; Debanne et al., 1996; Salin et al., 1996; Stoop and
Poo, 1996; Murthy et al., 1997; Gottschalk et al., 1998;
Hernandez-Echeagaray et al., 1998; Lessmann and Heumann, 1998; Emmerson
and Miller, 1999; Niittykoski et al., 1999; Stanford and Cooper, 1999;
Steffensen et al., 1999; Sullivan, 1999; Jiang et al., 2000; Poncer et
al., 2000; Yun et al., 2000; Cooper and Stanford, 2001; Rozov et al.,
2001). Although some inconsistencies have recently been reported for
some brain areas (Brody and Yue, 2000; Kraushaar and Jonas, 2000;
Waldeck et al., 2000), it is well established that changes in
transmitter release affect the paired-pulse ratio (PPR) in the VTA
(Bonci and Williams, 1997; Manzoni and Williams, 1999). In slices from
saline-treated mice, we observed paired-pulse facilitation (PPF), with
the second pulse evoking a GABAA IPSC (IPSC2)
that was significantly larger than the first (Fig.
1a,e; IPSC2/IPSC1 = 1.3 ± 0.06; n = 16). Conversely, ethanol-treated
mice exhibited paired pulse depression (PPD; Fig. 1b,e;
IPSC2/IPSC1 = 0.8 ± 0.02; n = 17;
p < 0.05). Thus, after a single in vivo
exposure to ethanol, the paired-pulse protocol resulted in PPD (Fig.
1c-e). PPF or PPD did not depend on the size of the first
GABAA IPSC (IPSC1; Fig. 1c) and was
not affected by changes in stimulus intensity (Fig. 1d). In
addition, we analyzed the PPR by dividing the mean of IPSC2 by the mean of IPSC1, and we find this method yields similar results
(p < 0.05; ethanol, IPSC2/IPSC1 = 0.7 ± 0.03; n = 17; saline, IPSC2/IPSC1 = 1.1 ± 0.06; n = 16).
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Figure 1.
Increased probability of GABA release 24 hr after
a single in vivo exposure to ethanol. GABAA
IPSCs from ethanol-treated mice show PPD compared with saline controls,
which show PPF. a, b, Examples of recordings from
saline-treated (a) and ethanol-treated
(b) animals. c, No correlation was
found between the amplitude of IPSC1 and the IPSC2/IPSC1 ratio in both
saline-treated mice (n = 16) and ethanol-treated
mice (n = 17). d, The IPSC2/IPSC1
ratio is independent of the stimulus strength. Results are the average
from four cells in each group of animals. e, PPD in
ethanol-treated mice is a long-lasting phenomenon. The bar
graph shows the average IPSC2/IPSC1 ratio (mean ± SEM) of
saline- and ethanol-treated mice after 1 d (n = 16 and 17 for saline and ethanol, respectively;
*p < 0.05), 1 week (n = 9 per
group; *p < 0.05), and 2 weeks
(n = 8 per group; p > 0.05)
after ethanol pre-exposure. f, Ethanol pre-exposure does
not change either number or function of postsynaptic GABAA
receptors. Bath application of GABA (100 µM, 3 min) in
the presence of GABAB receptor antagonist CGP 35348 (100 µM) elicited a similar current (30 sec bins) in both
groups of animals (n = 4; p > 0.05) when neurons were voltage-clamped at 70 mV.
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A change in PPR toward PPD might reflect changes in probability of
release, function of postsynaptic GABAA
receptors, or a combination of these. To determine whether changes in
GABAA receptor function, number, or both occurred
after in vivo ethanol administration, we bath
applied GABA (100 µM, 3 min)
in presence of the GABAB receptor
antagonist (3-aminopropyl)(diethoxymethyl) phosphinic acid
(CGP35348) (100 µM). The amplitude of the
inward current elicited by GABA did not differ between ethanol- and
saline-treated animals (n = 4 for each group;
p > 0.05; Fig. 1f). These results suggest that modifications in transmitter release, rather than in
postsynaptic receptors, occur after an in vivo exposure to ethanol.
To further test this possibility, we examined spontaneous
GABAA mIPSCs. Figure
2, a-c, shows that the
frequency of mIPSCs was significantly higher in ethanol- than in
saline-treated animals (ethanol, 2.8 ± 0.4 Hz; n = 9; saline, 0.7 ± 0.1 Hz; n = 7;
p < 0.05). Furthermore, there was no significant
difference in the amplitude of mIPSCs in the two groups, with mean
amplitudes of 30.4 ± 4.2 and 29.2 ± 3.4 pA in saline- and
ethanol-treated mice, respectively (Fig. 2c,d;
p > 0.05). Because an increase in frequency but not
amplitude of mIPSCs is generally thought to reflect a presynaptic
increase in probability of transmitter release (Malenka and Nicoll,
1999), both the paired pulse protocol and the increased frequency of
spontaneous events indicate that the probability of GABA release in the
VTA was increased 1 d after a single exposure to ethanol.
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Figure 2.
Ethanol pre-exposure increased the frequency, but
not amplitude, of spontaneous mIPSCs. a, Samples of
mIPSCs from saline-treated mice (top traces) and
ethanol-treated mice (bottom traces). b,
Bar graph showing the average (mean ± SEM)
frequency for saline-treated animals (n = 7) and
ethanol-treated animals (n = 9;
*p < 0.05). c, Bar
graph (10 pA bins) showing an amplitude histogram of mIPSCs for
ethanol-treated (n = 9) versus saline-treated
(n = 7) mice. d, Bar
graph showing the average (mean ± SEM) amplitude for
saline-treated animals (n = 7) and ethanol-treated
animals (n = 9).
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Previous in vivo studies have shown that reduced DAergic
activity persists long after somatic signs of withdrawal have subsided (Diana et al., 1996). Therefore, we collected evoked
GABAA IPSCs by using the paired-pulse protocol
both 1 and 2 weeks after the single in vivo exposure to
ethanol to determine how long the PPD lasted. Figure 1e
shows that PPD was still present after 1 week (ethanol,
IPSC2/IPSC1 = 0.9 ± 0.08; n = 9;
p < 0.05; saline, IPSC2/IPSC1 = 1.2 ± 0.08;
n = 7), but that within 2 weeks, the phenomenon had
subsided (ethanol, IPSC2/IPSC1 = 1.1 ± 0.06;
n = 8; p > 0.05; saline,
IPSC2/IPSC1 = 1.2 ± 0.05; n = 7). These data
are consistent with the idea that increased probability of GABA release
might contribute to the long-lasting hypoactivity of DA neurons that has been observed in vivo after ethanol exposure (Diana et
al., 1996).
Behavioral studies reported that a single in vivo exposure
to ethanol produced an increase in subsequent self-administration of
ethanol in rodents (Camarini et al., 2000; Files et al., 2000). In
addition, activation of GABAA receptors plays a
role in ethanol self-administration, because
GABAA agonists facilitate acquisition of
voluntary ethanol drinking in rats (Smith et al., 1992; Nowak et al.,
1998). We therefore decided to measure the ethanol consumption in mice
that underwent the same experimental protocol. To perform these
experiments, 24 hr after a single exposure to ethanol (2 gm/kg, i.p.),
mice were given a two-bottle choice test with two concentrations of
ethanol versus water for 5 d at each concentration (2 and 5% v/v,
respectively). We began with the lower concentration for 5 d to
allow the animals to acclimate to the taste of ethanol. As reported
previously (Camarini et al., 2000), C57BL/6J mice pretreated with
ethanol consumed more ethanol than saline controls after 10 d of
housing in the continuous access situation (Fig. 3a). We found that 10 d
after the acute exposure, the mean ethanol intake was 9.3 ± 0.6 and 7.4 ± 0.4 gm/kg for ethanol-treated (n = 8)
and saline-treated (n = 8) mice, respectively
(p < 0.05). Although both groups preferred
water to ethanol, ethanol-treated mice showed an increased preference
for ethanol (46.9 ± 0.5%; n = 8;
p < 0.05; Fig. 3b) when compared with
saline controls (41.1 ± 1.5%; n = 8). However,
because differential absorption, distribution, or clearance of ethanol
may contribute to the increased ethanol intake observed in
ethanol-treated mice, we measured blood ethanol concentrations 10-90
min after administration of ethanol (4 gm/kg, i.p.). Figure
3c shows that ethanol clearance did not differ between the
two groups of animals, although it showed lower blood ethanol levels
than commonly reported (Hodge et al., 1999; Thiele et al., 2000; Wand
et al., 2001). One possible explanation for such low levels might be
the faster metabolism of younger mice used for the present study
compared with the 2- to 4-month-old mice tested in other studies (Hodge
et al., 1999; Thiele et al., 2000; Wand et al., 2001). Nevertheless,
taken together, these results support the hypothesis that an increased
GABAergic transmission in the VTA may be involved in facilitating or
maintaining ethanol consumption (Smith et al., 1992; Nowak et al.,
1998).
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Figure 3.
One week after the pre-exposure, ethanol-treated
mice show increased ethanol intake and preference compared with saline
controls. a, Voluntary 24 hr ethanol consumption (grams
per kilogram) in C57BL/6J mice pretreated with ethanol
(n = 8; *p < 0.05) and saline
(n = 8). b, Ethanol preference,
calculated as 100 × milliliters of ethanol per total milliliters
consumed. C57BL/6J mice pretreated with ethanol demonstrated a
significant increase in ethanol preference (n = 8;
*p < 0.05) when compared with saline controls
(n = 8). c, Blood ethanol clearance
after acute administration of ethanol (4 gm/kg, i.p.) did not differ
between ethanol- and saline-treated mice. Data (mean ± SEM)
represent four animals per each group at every time point.
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The observed difference in PPR between the two groups of animals might
result indirectly from activation of presynaptic receptors. In the
midbrain, GABAB receptors are present
presynaptically and postsynaptically, and it has been shown that the
activation of presynaptic GABAB receptors causes
inhibition of GABAA IPSCs (Johnson and North,
1992b; Hausser and Yung, 1994). Therefore, to test the possibility that
increased probability of GABA release might raise GABA levels and thus
activate presynaptic GABAB receptors, we measured
the PPR in the presence of the GABAB receptor
antagonist CGP35348 (100 µM, 5 min). Figure
4, a and b, shows
that CGP35348 significantly shifted the PPD to PPF in ethanol-treated
animals (IPSC2/IPSC1 = 0.7 ± 0.04-1.2 ± 0.08;
n = 10; p < 0.05) by increasing the
amplitude of the second evoked GABAA IPSC (IPSC2,
140 ± 9%; data not shown) without affecting either
GABAA IPSC in the saline-treated animals
(IPSC2/IPSC1 = 1.5 ± 0.1-1.4 ± 0.2; n = 5; p > 0.05). In addition, both the frequency and
the amplitude of mIPSCs were unaffected by CGP35348 (100 µM, 5 min) in both groups of mice (frequency:
ethanol, 2.9 ± 0.2-2.6 ± 0.3 Hz; n = 7;
saline, 1.1 ± 0.1-1.1 ± 0.1 Hz; n = 7;
amplitude: ethanol, 33.6 ± 1.8-33 ± 2.9 pA;
n = 5; saline, 33.2 ± 2.1-26.9 ± 2.6 pA;
n = 7; Fig. 4c,d). Thus, the PPD observed in
the ethanol-treated mice could result from an increased probability of
GABA release, which might in turn lead to activation of presynaptic
GABAB receptors and decrease the IPSC2.
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Figure 4.
Effect of the GABAB receptor
antagonist CGP35348 (100 µM) on IPSC2/IPSC1 ratio and
spontaneous mIPSCs. a, CGP35348 (100 µM, 5 min) shifts the PPD to PPF in ethanol-treated mice
(n = 10; *p < 0.05), without
affecting the PPF in saline-treated mice (n = 5).
b, The IPSC2/IPSC1 ratio is plotted as a function of
time in cells recorded from saline- and ethanol-treated mice and
normalized against the mean of the first 10 min for each cell.
c, CGP35348 does not change the frequency of mIPSCs in
either group (n = 7 per each group).
d, No changes in amplitude of spontaneous mIPSCs were
found in either group (n = 7 per each group).
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An alternative interpretation of the present results is that the
sensitivity of presynaptic GABAB receptors might
be enhanced in the ethanol-treated animals. Therefore, we tested
differences in sensitivity of presynaptic GABAB
receptors by comparing the inhibition caused by the
GABAB receptor agonist baclofen in slices from
both saline- and ethanol-treated animals. Figure
5a shows that the
concentration-response curves to baclofen were similar in the saline-
and ethanol-treated mice (baclofen 0.1 µM:
ethanol, 22.3 ± 8.9%; n = 5; saline, 25.4 ± 3.1%; n = 5; baclofen 1 µM: ethanol, 42.8 ± 12.3%; n = 5; saline, 44.5 ± 2.3%; n = 5; baclofen 10 µM: ethanol, 70.6 ± 11.8%;
n = 5; saline, 72.7 ± 7.2%; n = 5). Because the amplitude of the IPSC1 was decreased in both groups of
animals to the same extent at all doses tested (Fig. 5a,b), we concluded that the increase in the IPSC2 observed in the presence of
CGP35348 in ethanol-treated animals did not result from altered sensitivity of GABAB receptors to endogenous
GABA. Additionally, a high dose of baclofen (10 µM; Fig. 5c,d) reverted the PPD to PPF in ethanol-treated mice (IPSC2/IPSC1 = 0.7 ± 0.02-1.2 ± 0.1; n = 5; p < 0.05), but it produced a nonsignificant increase in PPF in
saline-treated animals (IPSC2/IPSC1 = 1.2 ± 0.1-1.3 ± 0.1; n = 5). These results further support the
hypothesis that GABA levels are increased after ethanol exposure,
leading to spillover onto presynaptic GABAB
receptors, whose activation leads to inhibition of release (Hausser and
Yung, 1994). Because changes in the paired-pulse ratio generally
reflect changes in the probability of release, we expected baclofen to
increase PPF in the saline group. However, we did detect a
nonsignificant increase in the PPF during the application of baclofen
at this concentration (IPSC2/IPSC1 = 1.2 ± 0.09-1.3 ± 0.02; n = 5; p > 0.05) and at 1 µM (IPSC2/IPSC1 = 1.1 ± 0.07-1.2 ± 0.08; n = 5; p > 0.05) in the saline-treated animals. This indicates that the PPR
measure is not sensitive enough in this range to detect a decrease in
GABA release, possibly as a result of a ceiling effect.
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Figure 5.
Effect of the GABAB receptor agonist
baclofen on evoked IPSCs. a, Concentration-response
curve for baclofen measuring the amplitude of IPSC1 from saline- and
ethanol-treated animals (n = 5 per each group at
all doses tested). b, Baclofen (1 µM, 10 min) decreases the amplitude of IPSC1 in both saline- and
ethanol-treated mice to the same extent (n = 5 per
each group). c, Baclofen (10 µM, 10 min)
shifts the PPD to PPF in ethanol-treated mice (n = 5; *p < 0.05) without affecting the PPF in
saline-treated mice (n = 5). d,
IPSC2/IPSC1 ratio plotted as a function of time in cells recorded from
saline- and ethanol-treated mice (n = 5 per group;
*p < 0.05) and normalized against the mean of the
first 10 min for each cell.
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An increase in probability of GABA release has been described
previously during acute withdrawal from chronic morphine in several
brain regions, including the VTA (Bonci and Williams, 1997). In
particular, this phenomenon has been characterized as being
cAMP-dependent in the VTA (Bonci and Williams, 1997), the periaqueductal gray (Ingram et al., 1998), the NAcc (Chieng and Williams, 1998), and the dorsal raphe nucleus (Jolas et al., 2000). Ethanol and other drugs of abuse are known to modulate the
cAMP-protein kinase A (PKA) cascade within the mesolimbic system
(Hoffman and Tabakoff, 1990; Self et al., 1998; Spanagel and Weiss,
1999). Therefore, to examine the possibility that the cAMP-dependent pathway was modified in the ethanol-treated animals, we directly activated adenylyl cyclase (AC) by bath applying forskolin. Forskolin (10 µM, 10 min) augmented the IPSC1 in saline-treated
animals (Fig. 6a; 111.6 ± 17.4%; n = 5; p < 0.05) but had no
effect on the amplitude of the IPSC1 in ethanol-treated mice (23.1 ± 13.3%; n = 5). Thus, application of forskolin
decreased the paired-pulse ratio toward depression in slices from
saline-treated animals (Fig. 6b; IPSC2/IPSC1 = 1.4 ± 0.1-0.9 ± 0.1; n = 5; p < 0.05) but was without effect in slices from ethanol-treated animals (IPSC2/IPSC1 = 0.8 ± 0.05-0.7 ± 0.1;
n = 5). This supports the idea that activation of AC
increased the probability of GABA release. In addition, the frequency
of spontaneous mIPSCs was also significantly increased by forskolin in
saline-treated mice (0.7 ± 0.1-1.7 ± 0.3 Hz;
n = 7; p < 0.05; Fig. 6c)
but not in the ethanol-treated animals (2.6 ± 0.7-2.9 ± 1.0 Hz; n = 8; Fig. 6c). There was no significant difference in the amplitude of the mIPSCs in the absence or
presence of forskolin in slices from either group of animals (saline,
29.4 ± 2.5-31 ± 2.9 pA; n = 7; ethanol,
34 ± 4.2-26.5 ± 1.7 pA; n = 8; Fig.
6d). To rule out the possibility of nonspecific effects of
forskolin, we tested 1,9-dideoxyforskolin, an inactive analog of
forskolin (Seamon and Daly, 1985). Superfusion of 1,9-dideoxyforskolin (10 µM, 10 min) had no effect on IPSCs in
either group of animals (7.7 ± 3.3 and 1.1 ± 2.6% in
ethanol- and saline-treated mice, respectively; n = 4 for each group; data not shown). Taken together, these results suggest
that a saturation of AC might occur after a single in vivo
exposure to ethanol.
View larger version (34K):
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[in a new window]
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Figure 6.
Effect of forskolin on evoked and spontaneous
IPSCs. a, Forskolin (10 µM, 10 min)
increases the amplitude of evoked IPSC1 in saline-treated mice
(n = 5; *p < 0.05) but not
ethanol-treated mice (n = 5). b,
Forskolin (10 µM, 10 min) shifts the PPF to PPD in
saline-treated mice (n = 5; *p < 0.05) without affecting the PPD in ethanol-treated mice
(n = 5). The IPSC2/IPSC1 ratio is plotted as
function of time in cells recorded from saline- and ethanol-treated
mice and normalized against the mean of the first 10 min for each cell.
c, Forskolin (10 µM, 10 min) induces a
significant increase in the frequency of mIPSCs in saline-treated mice
(n = 7; *p < 0.05) but not in
ethanol-treated mice (n = 9). d, No
changes in amplitude were found in either group.
|
|
Because changes of intracellular cAMP levels subsequently alter PKA
activity, we tested the effect of
N-[2(p-bromocinnamylamino)ethyl]-5-isoquinolinesulfonamide (H89), which inhibits PKA in a competitive manner against ATP (Chijiwa
et al., 1990). Superfusion of H89 (10 µM, 20 min)
significantly reduced the amplitude of IPSC1 in ethanol-treated mice
(38.6 ± 5.4%; n = 5; p < 0.05;
Fig. 7a) but had no effect in
slices from control animals (3.4 ± 8.1%; n = 5).
The subsequent application of forskolin (10 µM,
10 min) in the presence of H89, used to test the activity of H89 in
control animals, did not change the amplitude of the IPSC1 in either
group (Fig. 7a). Furthermore, H89, by reducing the size of
IPSC1, shifted the PPD to PPF in slices from ethanol-treated animals
(IPSC2/IPSC1 = 0.8 ± 0.02-1.1 ± 0.01;
n = 5; p < 0.05; Fig. 7b).
Consistent with these results, H89 reduced the frequency of spontaneous
mIPSC in the ethanol-treated animals (2.6 ± 0.1-1.6 ± 0.1 Hz; n = 6; p < 0.05; Fig.
7c) but not in the saline-treated animals (0.9 ± 0.1-0.8 ± 0.1 Hz; n = 5); in the presence of
H89, the amplitude of spontaneous mIPSCs was not changed in either saline-treated mice (31.7 ± 5.2-31.3 ± 2.6 pA;
n = 5) or ethanol-treated mice (28.7 ± 3.1-24.8 ± 2.9 pA; n = 6). In conclusion, these
experiments indicate that PKA activity is significantly enhanced by a
single exposure to ethanol, and that such a phenomenon increases the probability of GABA release in the VTA.
View larger version (36K):
[in this window]
[in a new window]
|
Figure 7.
Effect of H89 on evoked and spontaneous IPSCs.
a, H89 (10 µM, 20 min) decreases the
amplitude of evoked IPSCs in ethanol-treated mice
(n = 5; *p < 0.05), but not
saline-treated mice (n = 5). b, H89
(10 µM, 20 min) shifts the PPD to PPF in ethanol-treated
mice (n = 5; *p < 0.05)
without affecting the PPF in saline-treated mice. c, H89
(10 µM, 20 min) induces a significant decrease in the
frequency of mIPSCs in ethanol-treated mice (n = 6;
*p < 0.05) but not saline-treated mice
(n = 5). d, No changes in amplitude
were found in either group.
|
|
| |
DISCUSSION |
In the present study, we observe that a single in vivo
exposure to ethanol produces a long-lasting increase in the probability of GABA release in the VTA, and that such an increase is dependent on
the activation of the cAMP-PKA signaling cascade. We hypothesize that
this type of plasticity may play an important role in determining the
increased alcohol consumption observed after a single exposure to
ethanol (Spanagel and Weiss, 1999; Camarini et al., 2000). Our data,
together with the fact that we and others have observed increased
ethanol consumption when mice were pre-exposed to ethanol, indicate
that increased probability of GABA release and increased ethanol
self-administration, both produced by the single ethanol injection,
might be strictly associated. Indeed, activation of GABAA receptors plays a role in ethanol
self-administration, because GABAA agonists
facilitate acquisition of voluntary ethanol drinking in rats (Smith et
al., 1992; Nowak et al., 1998). Accordingly, a role of
GABAA receptors within the VTA in mediating
ethanol intake has been suggested (Samson et al., 1987; Boyle et al., 1993; Rassnick et al., 1993b). Indeed, systemic administration of
GABAA receptor antagonists reduces intake (Boyle
et al., 1993) and operant responding for ethanol in rats (Samson et
al., 1987; Rassnick et al., 1993b). Consistent with these and previous
findings, intra-VTA infusions of GABAA receptor
antagonists decreased ethanol consumption in rats of the
alcohol-preferring P line (Nowak et al., 1998). To further support the
hypothesis that increased GABAergic activity produced by a single
in vivo exposure to ethanol plays a role in ethanol-related
behaviors, it has recently been shown that there is a direct
relationship between pretreatment with ethanol and enhanced
self-administration of ethanol in mice (Camarini et al., 2000).
Specifically, C57BL/6J mice pre-exposed to ethanol exhibited a
significant increase of ethanol intake, and DBA/2J mice, which normally
avoid oral ingestion of ethanol, did start to self-administer ethanol
in a two-bottle choice test.
In our first set of experiments, we show that a single injection of
ethanol shifted the paired-pulse modulation of
GABAA IPSCs from PPF to PPD. The paired pulse
stimulation is typically used as an electrophysiological protocol to
test for changes in probability of transmitter release (Zucker, 1989;
Stuart and Redman, 1991; Manabe et al., 1993; Mennerick and Zorumski,
1995; Debanne at al., 1996). Although this phenomenon is not always
use-dependent (Brody and Yue, 2000; Kraushaar and Jonas, 2000; Waldeck
et al., 2000), a variety of manipulations that increase transmitter
release, including exposure to drugs of abuse, have been found to shift the paired-pulse ratio from facilitation toward depression in the
hippocampus (Mennerick and Zorumski, 1995; Salin et al., 1996) and the
VTA (Bonci and Williams, 1997). Furthermore, the persistence of PPD 1 week after the ethanol injection suggests that increased GABAA-mediated inhibition may be considered a
measure of changes occurring at these synapses, eventually contributing
to the expression of ethanol-seeking behavior.
However, an increase in the probability of GABA release might simply be
one of many factors determining the shift from PPF to PPD in the
ethanol-treated animals. Although a desensitization of postsynaptic
GABAA receptors could account for PPD, we tend to
rule out that possibility, because the ethanol-treated animals show an
increase in mISPCs frequency but not in amplitude when compared with
the saline-treated animals. Furthermore, bath application of GABA, in
the presence of a GABAB receptor antagonist,
produces similar responses in saline- and ethanol-treated animals.
An alternative explanation for the observed PPD in the ethanol-treated
animals, is that activation of presynaptic GABAB
receptors might occur as a consequence of increased GABA levels
produced by the first evoked stimulus, thus reducing the amplitude of
IPSC2. Indeed, it has been shown that activation of
GABAB receptors inhibits GABAA IPSCs in the midbrain via a presynaptic
mechanism and therefore are considered to serve also as autoreceptors
(Hausser and Yung, 1994). Our results showing that the
GABAB antagonist CGP35348 shifted PPD to PPF in
animals injected with ethanol, but not in the saline controls, indicate
that presynaptic GABAB receptors might play a
minor role when probability of GABA release is relatively low, as in
the saline-injected animals. However, they might act as a negative
feedback mechanism to regulate GABAergic transmission within the VTA
when probability of GABA release is increased, such as after a single
in vivo exposure to ethanol. Thus, our data indicate that
increased GABA levels, by changing the spatial range of synaptically
released GABA, allow the activation of presynaptic GABAB receptors located on the GABAergic
interneurons, which in turn would prevent excessive
GABAA-mediated synaptic transmission (McCarren
and Alger, 1985; Deisz and Prince, 1989; Davies et al., 1990; Isaacson
et al., 1993).
Our results also suggest that the ethanol-induced increase in the
probability of GABA release was a result of saturation of the AC
cascade within GABAergic terminals. Forskolin, which enhanced the
amplitude of evoked IPSCs and the frequency of mIPSCs in saline-treated mice, had no effect in the ethanol-treated mice. In addition, the PKA
inhibitor H89 reduced the amplitude of evoked IPSCs and the frequency
of mIPSCs only in ethanol-treated animals, whereas it had no effect in
saline-treated animals. These findings suggest that a single in
vivo exposure to ethanol results in persistent enhancement of
PKA-dependent processes in GABAergic terminals in the VTA. It is
possible that because of high cAMP levels after the exposure to
ethanol, the catalytic subunits of the PKA complex become unbound and
freely diffuse within the terminals. In fact, in slices from
ethanol-treated animals, H89 revealed an increased basal activity of
PKA, and the activation of AC by forskolin was blunted. Consistent with
our findings, reduced signaling through the cAMP-PKA system, whether
because of decreased expression of the  subunit of the stimulatory
G-protein (Gs ) or inhibition of PKA, changed
C57BL/6J mice, considered to be an ethanol-preferring line of mice,
into ethanol nonpreferring mice (Wand et al., 2001). In addition,
alcohol-preferring rats show increased AC activity and expression of
Gs in mesolimbic regions when compared with
alcohol-nonpreferring rats (Froehlich and Wand, 1997). More generally,
our results are in agreement with previous studies reporting that
genetic manipulations of the cAMP-PKA pathway modulate ethanol intake
and sensitivity to its sedative effects (Thiele et al., 2000; Wand et
al., 2001). Although the relationships between the sedative and
rewarding effects of ethanol are complex, it is also important to
mention that the cAMP-PKA system has been implicated in neural
plasticity associated with drug tolerance and dependence (Self and
Nestler, 1995; Moore et al., 1998; Andretic et al., 1999; Yoshimura and
Tabakoff, 1999). Finally, it has been shown that chronic exposure to
many drugs of abuse, including ethanol, also leads to increased
activity of cAMP-dependent processes (Terwilliger et al., 1991; Dohrman
et al., 1996; Bonci and Williams, 1997).
In conclusion, our results provide evidence that a single in
vivo exposure to ethanol produces a long-lasting potentiation of
GABAergic synapses in the VTA. This cAMP-PKA-dependent plasticity occurring at these synapses might represent an important cellular signaling event underlying increased ethanol consumption. Whether these
changes are the result of a compensation for acute effects of ethanol
or manifestation of a long-lasting effect of acute ethanol remains to
be elucidated. Although acute effects of ethanol on the GABAergic
systems in the CNS are still a matter of debate, we tend to support the
latter possibility, because ethanol has been found to enhance GABAergic
transmission in several brain regions (Celentano et al., 1988; Deitrich
et al., 1989; Aguayo and Pancetti, 1994; Mehta and Ticku, 1994; Wan et
al., 1996; Nie et al., 2000), including the VTA (M. Melis and A. Bonci,
unpublished observations). In conclusion, we observed that a single
in vivo ethanol exposure induces a long-lasting potentiation
of GABA synaptic transmission within the VTA via a cAMP-PKA mechanism,
and that it appears to be directly related to increased ethanol
consumption and may therefore be involved in the development of alcoholism.
| |
FOOTNOTES |
Received Nov. 6, 2001; revised Dec. 17, 2001; accepted Dec. 28, 2001.
This work was supported by funds provided by the State of California
for medical research on alcohol and substance abuse through the
University of California, San Francisco, and by the Department of the
Army, award number DAMD17-01-10736, United States Army Medical Research
Acquisition Activity (Fort Detrick, MD). The content of the information
does not necessarily reflect the position or the policy of the
Government, and no official endorsement should be inferred. We thank
all members of the Bonci Lab for many helpful discussions and inputs.
We also deeply thank the late Dr. Thomas Dunwiddie for his many helpful
insights. He will be sorely missed in the future.
Correspondence should be addressed to Antonello Bonci at the above
address. E-mail: bonci{at}itsa.ucsf.edu.
| |
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TOP
ABSTRACT
INTRODUCTION
