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The Journal of Neuroscience, December 1, 2002, 22(23):10487-10493
Low Ethanol Sensitivity and Increased Ethanol Consumption in Mice
Lacking Adenosine A2A Receptors
Mickaël
Naassila1,
Catherine
Ledent2, and
Martine
Daoust1
1 Laboratoire de Physiologie-Alcoologie,
Université de Picardie Jules Verne, Faculté de Pharmacie,
80000 Amiens, France, and 2 Institut de Recherche
Interdisciplinaire, Université Libre de Bruxelles, B-1070
Brussels, Belgium
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ABSTRACT |
We have shown previously that the severity of handling-induced
convulsions during ethanol withdrawal was reduced in A2A
receptor knock-out (A2AR /)
mice. In the present report, we further characterize the role of
adenosine A2A receptors in ethanol consumption and
neurobiological responses to this drug of abuse. Male
A2AR/ mice showed increased
consumption of solutions containing 6 and 20% (v/v) ethanol compared
with wild-type (A2AR+/+) control mice;
female A2AR/ mice showed increased
consumption of solutions containing 6 and 10% ethanol. This slightly
higher ethanol consumption was also related to increased ethanol
preference. In contrast, A2AR/ mice
showed normal consumption of solutions containing either sucrose or
quinine. Relative to A2AR+/+ mice,
A2AR/ mice were found to be less
sensitive to the sedative effect of 3.0 gm/kg ethanol, as measured by
more rapid recovery from ethanol-induced loss of righting reflex, and
to the hypothermic effects of 1.5, 3.0, and 4.0 gm/kg ethanol, although
plasma ethanol levels did not differ significantly between the two
genotypes. The selective adenosine A2A receptor antagonist
ZM 241385 (4-(2-[7-amino-2-(2-furyl)[1,2,4]triazolo[2,3-a][1,3,5]triazin-5-ylamino]ethyl)phenol) (10-30 mg/kg) significantly attenuated ethanol-induced (4.0 gm/kg) hypothermia in CD1 mice. To assess whether ethanol administration would
induce differential tolerance in
A2AR/ and wild-type mice, we
administered ethanol (3.0 gm/kg) over 4 consecutive days and found no
difference in the development of tolerance; however, female
A2AR/ mice showed a lower
tolerance-acquisition rate. These data suggest that activating the
A2A receptors may play a role in suppressing alcohol-drinking behavior and is associated with the sensitivity to the
intoxicating effects of acute ethanol administration.
Key words:
adenosine; A2A receptor; ethanol; hypothermia; knock-out mice; sensitivity; tolerance; ZM 241385
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INTRODUCTION |
Extracellular adenosine is an
important signaling molecule that modulates diverse neuronal functions
via four G-protein-coupled receptor subtypes: the
A1, A2A,
A2B, and A3 receptors
(Fredholm et al., 2001 ). This neuromodulator can either inhibit or
facilitate synaptic transmission via A1 and
A2A receptor (A2AR)
activation, respectively. In the brain, the distribution of
A2ARs is primarily restricted to the striatum and
nucleus accumbens (Jarvis and Williams, 1989), which is consistent with
the proposed role of these receptors in modulating dopaminergic
neurotransmission. In these regions, A2AR
activation has been shown to stimulate dopamine release and/or synthesis (Onali et al., 1988; Okada et al., 1996, 1997) [although this effect has not been replicated in the study by Jin and Fredholm (1997)] and negatively modulate the postsynaptic effects of dopamine (Ferré et al., 1991, 1993).
There is strong evidence for an involvement of the adenosinergic system
in some of the central effects of ethanol at the cellular and molecular
levels (Diamond and Gordon, 1994) and also at the behavioral level. In
this regard, A1 and A2A
receptors have been shown to be involved in mediating ethanol-induced
motor incoordination in the rat, with a predominant role of the
A1 receptor, by the use of agonists and
antagonists (Meng and Dar, 1995) and antisense oligodeoxynucleotide
specifically directed against the A1 receptor (Phan et al., 1997; Nyce, 1999). In mice, chronic ingestion of the
nonselective antagonist caffeine has been shown to reduce the locomotor
stimulant effects of ethanol (Daly et al., 1994). In addition, single
and repeated episodes of ethanol withdrawal have been shown to increase
A1 but not A2 receptor
density in the mouse brain (Jarvis and Becker, 1998).
Recently, an A2AR knock-out mouse has been
characterized as being hypertensive, aggressive, anxious, and
hypoalgesic (Ledent et al., 1997); we have shown that the severity of
handling-induced convulsions during ethanol withdrawal was reduced in
this A2AR knock-out mouse (El Yacoubi et al.,
2001). This mouse model has also been shown to be characterized by a
functional hypodopaminergic state corresponding to a 45% decrease in
the extracellular concentration of dopamine in the striatum, associated
with upregulation of D1 and D2 dopamine receptor expression (Dassesse
et al., 2001). Because the dopaminergic neurotransmission between the
ventral tegmental area and the limbic forebrain is a critical
neurobiological component of alcohol and drug self-administration (Di
Chiara and Imperato, 1988; Weiss and Porrino, 2002), brain
A2A adenosine receptors may provide a novel
target for the modulation of alcohol drinking behavior. Ethanol
self-administration is decreased in D1- or D2-deficient mice (El-Ghundi
et al., 1998; Risinger et al., 2000), and the highly alcohol-preferring
C57BL/6J mouse strain (Belknap et al., 1993) has been shown to present
low nigrostriatal/mesolimbic dopaminergic activity (George et al.,
1995), so that the low availability of synaptic dopamine has
been postulated to increase ethanol preference.
Because A2AR knock-out mice have been
characterized by a functional hypodopaminergic state, we postulated
that these mice would display increased alcohol drinking and altered
sensitivity and tolerance to some ethanol effects.
To more clearly understand the role of the A2AR
in mediating the effects of ethanol, we studied ethanol consumption and
the hypothermic/sedative effects of ethanol in
A2AR knock-out mice. We also investigated the
effect of a selective A2AR antagonist on
ethanol-induced hypothermia in CD1 mice.
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MATERIALS AND METHODS |
Animals. Adult female and male wild-type and
A2AR/ mice
(8-14 weeks of age) generated on a CD1 background as described
previously (Ledent et al., 1997) and weighing 20-30 gm were used. The
first-generation chimeric (129SvJ × CD1) heterozygotes were bred
for 15 generations on a CD1 (Charles River, St. Germain sur
l'Arbresle, France) outbred background, to dilute the genetic
background of the embryonic stem cells derived from the 129SvJ mouse
strain, with selection for the mutant A2A
gene at each generation. Fifteenth-generation heterozygotes were
bred together to generate A2AR-deficient and control mice. All animals used in a given experiment originated from
the same breeding series and were matched for age and weight. Experiments were also performed on adult male albino CD1 mice (Charles
River, Saint Aubin les Elbeuf, France). Mice were housed in groups of
10 in clear plastic cages and maintained in a temperature-controlled (~22°C) and humidity-controlled room on a 12 hr light/dark cycle. The number of animals was kept to a minimum. All efforts were made to
avoid making the animals suffer; the procedures described comply with
ethical principles and guidelines for the care and use of laboratory
animals adopted by the European Community, law 86/609/European Economic Community.
Alcohol intake test. Data for the alcohol intake study were
collected from two experiments. Throughout the experiments, fluid intake and body weight were assessed every 2 d.
A2AR/ mice
(male, n = 34; female, n = 19) and
A2AR+/+ mice (male,
n = 29; female, n = 18) were
individually housed in plastic mouse cages with access ad
libitum to standard rodent chow and habituated in their home cage
to drinking from two bottles containing plain water for 1 week. Mice
were then given access for 48 hr to two bottles, one containing water
and the other containing ethanol in water. The ethanol concentration
(v/v) was increased every 6 d; mice received 3, 6, 10, and finally
20% ethanol over the course of the experiment. The positions of the
bottles were changed every 2 d to control for position
preferences. Average ethanol consumption per day was obtained for each
ethanol concentration. To obtain a measure of ethanol consumption that
corrected for individual differences in mouse size, grams of ethanol
consumed per kilogram of body weight per day were calculated for each
mouse. As a measure of relative ethanol preference, an ethanol
preference ratio was calculated by dividing the total ethanol solution
consumed by total fluid (ethanol plus water) consumption. Two-way
2 × 4 (genotype × concentration) and 2 × 3 (genotype × trial) ANOVAs were used for statistical analysis.
Sucrose and quinine consumption test.
A2AR/ (male,
n = 8; female, n = 8) and wild-type
(male, n = 8; female, n = 8) mice were habituated in their home cage to drinking from two bottles containing water for 1 week and were then given plain water in one bottle and
sucrose or quinine in the other bottle. The compounds were presented in
the following order: sucrose solutions (1.70 and 4.25%) followed by
quinine solutions (0.03 and 0.10 mM). Mice had 48 hr of access to each solution, and the position of the solution was
counterbalanced between animals. The preference for each solution was
assessed by dividing the volume of the taste solution consumed by the
total volume of fluid (water plus taste solution) consumed to obtain a
preference ratio. The data collected with each taste solution were
analyzed separately with two-way 2 × 2 (genotype × concentration) repeated-measures ANOVA.
Test for sensitivity to the sedative/hypnotic effects of
ethanol.
A2AR/ (male,
n = 20; female, n = 20) and wild-type
(male, n = 25; female, n = 21) mice
were removed from their home cage and given an intraperitoneal injection of ethanol [3.0 and 4.0 gm/kg, 20% (w/v) mixed in isotonic saline]. At the onset of ethanol-induced sedation, each mouse was
placed on its back in a plastic U-shaped trough. The time (in minutes)
that elapsed between the ethanol injection and when the mouse could
right itself onto all four paws, measured three times within a 30 sec
interval, was used as the index of time to regain the righting reflex.
These data were analyzed with a Student's t test.
Test for sensitivity and tolerance to ethanol-induced
hypothermia. To measure hypothermia to acute ethanol
administration, rectal temperature was measured using a KJT
thermocouple (Bioseb, Paris, France) at room temperature
(22°C) before and after an intraperitoneal ethanol injection. Three
ethanol doses were tested: 1.5, 3.0, and 4.0 gm/kg body weight [20%
ethanol (w/v) mixed in isotonic saline]. Rectal temperature was
assessed every 30 min after ethanol administration.
A 4 d tolerance paradigm was used to assess whether ethanol
administration could induce differential tolerance development in
A2AR/ and
wild-type mice. Immediately after recording the baseline temperature on
day 1, all mice,
A2AR/ (male,
n = 10; female, n = 8) and wild type
(male, n = 8; female, n = 13), received
an intraperitoneal injection of 3.0 gm/kg ethanol [20% (w/v) mixed in
isotonic saline]. Injections and testing were conducted daily for 4 consecutive days, and tolerance development was analyzed at 30, 60, 90, and 120 min after the injection of ethanol. Two-way 2 × 4 (genotype × day) ANOVA and Student's t test for the
comparison of slopes were used for statistical analysis. It should be
noted that our paradigm was used to measure behavioral tolerance, but
the development of metabolic tolerance was not analyzed. To verify that
the absence of the A2A receptor in knock-out mice
could be mimicked by the administration of drugs, we also tested the
effect of the selective A2A receptor antagonist
4-(2-[7-amino-2-(2-furyl)[1,2,4]triazolo[2,3-a][1,3,5]triazin-5-ylamino]ethyl)phenol (ZM 241385) (Sigma Aldrich, Paris, France) (Poucher et
al., 1995) on ethanol-induced (4.0 gm/kg) hypothermia. The compound was
dissolved in DMSO (15%), stabilized with Cremophor EL (15%), diluted
in 0.9% saline (70%), prepared fresh daily, and administered
intraperitoneally 15 min before ethanol injection. One group of mice
received vehicle (15% DMSO, 15% Cremophor EL, 70% NaCl 0.9%) 15 min
before ethanol injection.
Plasma ethanol concentrations. We took ~20 µl of tail
blood samples at the indicated time points after an intraperitoneal injection of ethanol (4.0 gm/kg body weight) [20% (w/v) prepared in
saline]. Samples were microcentrifuged for 10 min (14,000 rpm) at
4°C and analyzed immediately. Plasma ethanol was determined by an
alcohol dehydrogenase/reduced nicotinamide adenine dinucleotide assay (Sigma Diagnostic, Paris, France) according to the
manufacturer's instructions. An ethanol standard solution (0.08%) was
used to generate a standard curve (and linear regression analysis) for each experiment, and plasma ethanol levels were calculated in milligrams per deciliter. Two-way 2 × 2 (time × genotype)
ANOVAs were used for statistical analysis.
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RESULTS |
Alcohol, sucrose, and quinine consumption tests
Male A2AR/
mice consumed significantly more ethanol (grams per kilogram per 24 hr)
than wild-type mice (F(1,692) = 15.22;
p < 0.001); their preference ratios were also
significantly greater (F(1,692) = 5.97; p = 0.01) (Fig.
1a,b). Male
A2AR/ mice drank
significantly more 6 and 20% ethanol solutions
(p < 0.001 and p = 0.004, respectively).
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Figure 1.
Ethanol consumption and preference in
A2AR/ (male, n = 34; female, n = 19) and
A2AR+/+ (male, n = 29; female, n = 18) mice. a,
Consumption (grams per kilogram per day) of each ethanol solution
(average of 6 d). b, Ethanol preference ratios
(volume of ethanol consumed/total volume of fluid consumed) as a
measure of relative ethanol preference during the consumption of each
ethanol solution. All values are means ± SEM. ANOVAs indicated
that male A2AR/ mice drank
significantly more 6 and 20% ethanol solutions, and that female
A2AR/ mice drank significantly more
6 and 10% ethanol solutions than their wild-type littermate control
mice; *p < 0.05; **p < 0.01;
***p < 0.001.
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Female A2AR/
mice consumed significantly more ethanol than the wild-type mice
(F(1,385) = 6.48; p = 0.01); their preference ratios were also significantly greater
(F(1,385) = 3.87; p = 0.04) (Fig. 1a,b). Female
A2AR/ mice drank
significantly more 6 and 10% ethanol solutions
(p < 0.05).
To determine whether these differences might reflect a more global
change in taste preferences, we tested
A2AR/ and
wild-type mice with sucrose and quinine solutions, using the same
protocol as above. No significant difference between the genotypes was
observed for the consumption of either sucrose (male,
F(1,56) = 2.89, p = 0.09; female, F(1,56) = 0.09, p = 0.76) or quinine (male,
F(1,126) = 2.34, p = 0.12; female, F(1,136) = 0.58, p = 0.44) solutions, showing that the increased
consumption of alcohol by A2AR knock-out mice
does not appear to be associated with an altered taste preference or
caloric need (Fig. 2a,b). The
preference ratios obtained in the present study are similar to values
published previously (Thiele et al., 1998, Wand et al., 2001).
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Figure 2.
a, b, Preference ratios for sucrose
(Suc) and quinine (Qui) (volume of taste
solution consumed/total volume of fluid consumed) in
A2AR/ (male, n = 8; female, n = 8) and
A2AR+/+ (male, n = 8; female, n = 8) mice. c, Plasma
ethanol concentration after ethanol injection (4.0 gm/kg, i.p.). All
values are means ± SEM (n = 6 mice in each
group). ANOVAs indicated that there were no significant genotype
differences for either sucrose and quinine preference ratios or ethanol
metabolism.
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Total fluid consumption (in milliliters) indicated that mutant and
wild-type mice did not differ in terms of the volume of fluid consumed
(data not shown), indicating that the increased ethanol consumption by
the null mutants was not caused by an overall increase in the total
amount of fluid consumed. There was also a significant effect of
gender, with female mice consuming more ethanol than male mice
(A2AR/,
F(1,586) = 46.25, p < 0.001; A2AR+/+,
F(1,491) = 32.78, p < 0.001); preference ratios were also significantly greater in the female
mice (A2AR/,
F(1,586) = 20.73, p < 0.001; A2AR+/+,
F(1,491) = 12.76, p < 0.001).
Ethanol-induced sedation and hypothermia and plasma
ethanol levels
Male and female
A2AR/ mice were
less sensitive to the sedative effects of ethanol, regaining their
righting reflex sooner than A2AR+/+ mice after
the injection of the 3.0 gm/kg ethanol dose
(F(3,86) = 17.64; p < 0.001); however, no difference was observed after the injection of the
4.0 gm/kg ethanol dose (F(3,80) = 0.01; p = 0.90) (Fig. 3).
A gender effect was also observed at the 3.0 gm/kg ethanol dose but not
at the 4.0 gm/kg dose, revealing that male mice were more sensitive to
the hypnotic effects of ethanol than female mice at the 3.0 gm/kg dose
(3.0 gm/kg, F(3,86) = 26.64, p < 0.001; 4.0 gm/kg,
F(3,80) = 2.55, p = 0.11).
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Figure 3.
The time elapsed between intraperitoneal
injections of ethanol (3.0 and 4.0 gm/kg) and righting of the mouse on
all four paws three times within a 30 sec interval was used as an index
of righting latency. All values are means ± SEM for
A2AR/ mice (male,
n = 20; female, n = 20) and
wild-type mice (male, n = 25; female,
n = 21). ANOVA indicated that
A2AR/ mice recovered from
ethanol-induced sedation significantly earlier than
A2AR+/+ mice at the 3.0 gm/kg ethanol
dose but not at the 4.0 gm/kg ethanol dose; ***p < 0.001 compared with A2AR+/+ mice;
###p < 0.001 compared with the
respective group at the 3.0 gm/kg ethanol dose.
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Ethanol-induced hypothermia was dose-dependent in all groups of
mice, as shown in Figure 4a,b.
There was a significant difference for body temperature change at 2 hr
with the main effects of dose (males,
F(2,69) = 21.18, p < 0.001; females, F(2,57) = 3.60, p < 0.03) and genotype (males,
F(1,69) = 6.93, p = 0.01; females, F(1,57) = 4.17, p = 0.04) (Fig. 4b). No main gender effect
was observed for the sedative effect of the 4.0 gm/kg ethanol dose (A2AR/,
F(1,225) = 2.49, p = 0.12; A2AR+/+,
F(1,225) = 1.86, p = 0.17). Male
A2AR/ mice were
less sensitive to the hypothermic effects of ethanol than their
wild-type littermates at all doses (1.5 gm/kg,
F(1,92) = 5.54, p = 0.02; 3.0 gm/kg, F(1,72) = 8.94, p = 0.004; 4.0 gm/kg, F(1,252) = 32.62, p < 0.001). In contrast, for the females, a difference in sensitivity was
observed only at the highest dose of ethanol (1.5 gm/kg,
F(1,56) = 0.52, p = 0.47; 3.0 gm/kg, F(1,84) = 1.06, p = 0.31; 4.0 gm/kg,
F(1,198) = 18.24, p < 0.001).
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Figure 4.
a, Mean change from baseline
temperature every 30 min for 2 hr after the intraperitoneal injection
of ethanol (1.5, 3.0, and 4.0 gm/kg) in male and female
A2AR/ and
A2AR+/+ mice (n = 6-10 mice in each group). b, Dose effect of ethanol on
the body temperature change 2 hr after intraperitoneal ethanol
injection. All values are means ± SEM. ANOVA indicated that
ethanol-induced hypothermia was dose-dependent in all groups of mice.
Moreover, male A2AR/ mice were less
sensitive to the hypothermic effects of ethanol than their wild-type
littermates at all doses of ethanol; female
A2AR/ mice were also less sensitive
than their wild-type littermates, but only at the highest dose of
ethanol.
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These differences in sensitivity to the sedative and hypothermic
effects of ethanol (and ethanol consumption) do not appear to be
secondary to differences in the acute clearance of ethanol, because
plasma ethanol concentrations after 4 gm/kg ethanol administration did
not differ between the genotypes (males,
F(1,48) = 0.05, p = 0.81; females, F(1,48) = 0.01, p = 0.89) (Fig. 2c). Body temperature recovery was obtained after ~7 hr, corresponding to the time of plasma ethanol clearance (data not shown).
Effect of treatment with the selective antagonist (ZM 241385)
on ethanol-induced hypothermia in male CD1 mice
The effect of ZM 241385 was studied on male CD1 mice,
corresponding to the genetic background used to generate the
A2AR/ mice. The
group of mice given ZM 241385 showed a significant decrease in
sensitivity to acute ethanol-induced hypothermia at the 4.0 gm/kg dose
(Fig. 5). The two-way ANOVA revealed a
main effect of the ZM 241385 treatment
(F(3,152) = 26.65; p < 0.001) but no significant interaction
(F(3,152) = 0.24; p = 0.98) between the treatment and time factors. The difference between
vehicle-treated mice and ZM 241385-treated mice was significant
starting at the 20 mg/kg dose of ZM 241385 (F(1,80) = 14.41; p < 0.001). In addition, the sedative effect induced by the injection of
ethanol (4.0 gm/kg) was also significantly reduced in the group of mice
treated with ZM 241385 (21 ± 4 min), but only at the highest dose
(30 mg/kg) (data not shown; one-way ANOVA followed by Dunn's
post hoc test; F(3,41) = 4.87; p = 0.005). A group of mice was also used to
check that treatment with ZM 241385 had no effect on body temperature (F(4,30) = 0.18; p > 0.80).
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Figure 5.
Effect of acute treatment with the selective
A2AR antagonist ZM 241385 (10-30 mg/kg) on ethanol-induced
(4.0 gm/kg, i.p.) hypothermia in male CD1 mice. Mice were treated with
the antagonist 15 min before ethanol injection; control mice were
treated with the vehicle. All values are means ± SEM
(n = 10 mice in each group). ANOVA indicated that
the group of mice given ZM 241385 (20-30 mg/kg) showed a significant
decrease in sensitivity to acute ethanol-induced hypothermia compared
with the vehicle group.
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Tolerance to ethanol-induced hypothermia
Both A2AR/
and wild-type mice developed a tolerance to 3.0 gm/kg ethanol-induced
hypothermia after repeated injections over 4 d (Fig.
6a,b). Two-way ANOVA showed a
significant day effect at all times tested for males (30 min,
F(1,66) = 5.27, p = 0.003; 60 min, F(1,59) = 6.79, p < 0.001; 90 min,
F(1,67) = 5.36, p = 0.002; 120 min, F(1,64) = 3.21, p = 0.03) and at 60, 90, and 120 min for females (30 min, F(1,81) = 2.34, p = 0.08; 60 min, F(1,81) = 5.65, p = 0.002; 90 min,
F(1,81) = 6.35, p < 0.001; 120 min, F(1,76) = 3.80, p = 0.01). There was a main effect of genotype in male
mice at 30, 60, and 90 min (30 min,
F(1,66) = 25.65, p < 0.001; 60 min, F(1,59) = 7.57, p = 0.008; 90 min,
F(1,67) = 7.21, p = 0.009; 120 min, F(1,64) = 3.12, p = 0.83), whereas no genotype effect was observed in
females at all times tested (30 min,
F(1,81) = 0.23, p = 0.63; 60 min, F(1,81) = 0.01, p = 0.91; 90 min,
F(1,81) = 0.06, p = 0.08; 120 min, F(1,76) = 0.09, p = 0.75), demonstrating a difference in the
sensitivity to 3.0 gm/kg ethanol-induced hypothermia between males but
not between females. No difference in the tolerance acquisition rate
was observed between male
A2AR/ and
wild-type mice at all times tested (p > 0.05;
Student's t test), whereas female wild-type mice had a
greater tolerance acquisition rate at both 90 and 120 min
(p < 0.05; Student's t test).
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Figure 6.
Tolerance development to ethanol-induced (3.0 gm/kg) hypothermia over 4 consecutive days in male
(a) and female (b)
A2AR/ (male, n = 10; female, n = 8) and
A2AR+/+ (male, n = 8; female, n = 13) mice. All values are means ± SEM. There was no difference in the tolerance acquisition rate
between male A2AR/ and wild-type
mice at all times tested (p > 0.05;
Student's t test), whereas female wild-type mice had a
higher tolerance acquisition rate at both 90 and 120 min
(p > 0.05; Student's t
test).
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DISCUSSION |
The overall finding in this set of studies is that mice lacking
the A2A receptor are less sensitive to the acute
effects of ethanol and consume more ethanol in a two-bottle choice
paradigm compared with wild-type littermate control mice.
Females of both genotypes consumed more ethanol than males (Fig. 1),
consistent with published data (Middaugh et al., 1999). Female
A2AR/ mice
consumed significantly more of the 6 and 10% ethanol solutions, but
unlike male
A2AR/ mice, they
did not show significant altered consumption of the 20% ethanol
solution, suggesting a possible interaction between gender and
expression of phenotypes associated with the gene mutation (Fig.
1a). A similar interaction has been suggested in previous reports (Hall et al., 2001; Thiele et al., 2002). This increased ethanol consumption was also associated with an increased ethanol preference, but it is important to point out that the ethanol preference ratios were low. Therefore, the increased ethanol preference observed in the knock-out mice was not indicative of a high preference for ethanol. Both
A2AR/ and
A2AR+/+ mice
preferred water to ethanol (preference ratios, <0.50); this phenotype
may be dependent on the genetic background. In this regard, it has been
shown previously that wild-type mice with a CD1 background had
an approximately twofold decrease (0.29 vs 0.70) in the ethanol
preference ratio compared with mice with a C57BL/6 background
(Wand et al., 2001). Increased ethanol consumption in
A2AR/ mice does
not appear to be related to the taste of ethanol, because these mice
showed normal consumption of solutions containing either sucrose or
quinine (Fig. 2a,b). Furthermore, increased consumption and
resistance to the acute effects of ethanol are not related to
differences in ethanol metabolism, as demonstrated by the identical blood ethanol elimination curves after intraperitoneal administration in A2AR/ and
A2AR+/+ mice (Fig.
2c). Importantly, these data present the first direct evidence that the adenosine A2AR is involved in
ethanol-drinking behavior.
Hypothermic and sedative effects after the acute administration of
ethanol have been well documented in rodents (Erwin et al., 1990);
studies in rodents have supported the idea that high levels of ethanol
drinking are often associated with resistance to the intoxicating
effects produced by this psychoactive substance. For example, rats that
have been selectively bred for high ethanol consumption
(alcohol-preferring rats) are more resistant to the impairing effects
of acute ethanol injection compared with non-alcohol-preferring rats
(Kurtz et al., 1996). Moreover, reduced initial sensitivity to alcohol
has been demonstrated in at-risk populations (for review, see Schuckit,
1987). In the present study, we report that mice lacking the
A2A receptor are less sensitive to acute
ethanol-induced hypothermia (Fig. 4) and sedation (Fig. 3), and that
this resistance is associated with increased ethanol consumption. It
should be noted that at the highest dose of ethanol (4.0 gm/kg), this
difference in sensitivity is observed for the hypothermic effects but
not for the sedative effects. These two responses to acute ethanol injection can be dissociated, because animal studies have shown that
ethanol-induced hypothermia and loss of the righting reflex are
polygenic traits (Erwin et al., 1990). Our results demonstrate that the
difference in the acute effects of ethanol is associated with a lack of
A2AR, because the effects of ethanol, both
hypothermia and sedation, are reduced by acute treatment with the
selective A2AR antagonist ZM 241385 (20-30
mg/kg) (Fig. 5). Because the selective antagonist causes an attenuation
of ethanol-induced hypothermia, it is possible to speculate that this
antagonist would also increase voluntary ethanol drinking. This
resistance to the acute effects of ethanol is also associated with a
decrease in ethanol withdrawal-induced convulsions, because after
chronic consumption of an ethanol diet,
A2AR/ mice
demonstrated less severe withdrawal signs than wild-type mice, and
treatment of CD1 mice with the A2A receptor
selective antagonist ZM 241385 (20 mg/kg) significantly reduced the
handling-induced convulsion score after chronic alcohol exposure (El
Yacoubi et al., 2001).
On the one hand, these differences in ethanol consumption might be
related to the basal-level anxiety differences between A2AR/ and
wild-type mice, because
A2AR/ mice have
more anxiety-related behavior, as indicated by the open-field test, the
elevated plus-maze test, and the black-and-white compartments test
(Ledent et al., 1997). Because ethanol has anxiolytic properties
(Stewart et al., 1993), it is possible that
A2AR/ mice
consume more ethanol to modulate anxiety. In this regard, alcohol-preferring rats have been shown to be more anxious
and/or emotional than alcohol-nonpreferring rats in some tests
(Stewart et al., 1993). On the other hand, because a functional
striatal hypodopaminergic state has been described in
A2AR/ mice
(Dassesse et al., 2001), it is possible that increased ethanol consumption is related to dysfunction of the dopaminergic system in the
mesocorticolimbic reward pathway. Like most drugs of abuse, ethanol
acutely elevates extracellular dopamine concentrations in the nucleus
accumbens; this modulation of mesolimbic dopamine transmission
represents a substrate for the positive reinforcing actions of ethanol
(Di Chiara and Imperato, 1988; Koob, 1992). The threshold to the
rewarding effects of ethanol could be altered in
A2AR/ mice
compared with their wild-type littermate controls. In this regard,
selective A2AR agonists have been found to
attenuate the rewarding effects of brain stimulation, suggesting that
adenosine, via A2AR, may inhibit central reward
processes (Baldo et al., 1999).
The neurochemical mechanism underlying this altered behavioral response
to ethanol in
A2AR/ mice is
unknown. Adenosine regulates neurotransmitter release, often in a
facilitatory manner, by acting via A2AR; some
effects on the release of GABA, dopamine, acetylcholine, and glutamate have been reported in the striatum (for review, see Svenningsson et
al., 1999). Synaptosomal preparations from transgenic mice lacking
functional A2AR show decreased dopamine release
compared with preparations from control animals (Chen et al., 1998).
Therefore, A2AR may regulate dopamine release,
but the evidence has not been consistently demonstrated (Jin and
Fredholm, 1997); this regulation may be secondary to the effects on the
release of other neurotransmitters. Another mechanism could involve the
lack of functional interaction between A2AR and
dopamine receptors in
A2AR/ mice. In
this regard, it has been shown that A2AR agonists
exert their actions by decreasing the affinity of dopamine D2 receptors (Ferré et al., 1991).
Repeated exposure to ethanol results in decreased responsiveness to the
effects of ethanol on the CNS. This adaptation, referred to as
tolerance, is observed in animals and humans and is influenced by
environmental factors and by genotype in rodents. Tolerance to ethanol
is a complex phenomenon, appearing in chronic, rapid, and acute forms
that are largely dependent on the amount and schedule of ethanol
exposure and the behavioral paradigm used to measure tolerance (Le,
1990; Khanna et al., 1993). Numerous studies have shown this phenomenon
in motor-impairment and hypothermia tests. As for the decreased initial
sensitivity to ethanol, increased tolerance development in humans has
been associated with a risk for alcoholism (Newlin and Thomson, 1991).
Our results show that the tolerance observed with our paradigm does not
appear to be a good predictive factor for the high level of ethanol
intake, because no clear difference in the development of tolerance was observed between
A2AR/ and
A2AR+/+ mice (Fig.
6). All mice developed tolerance to the hypothermic effects of acute
injection of ethanol (3.0 gm/kg) over 4 consecutive days. However, the
greater sensitivity to ethanol observed in female
A2AR+/+ mice was
associated with the more rapid acquisition of tolerance at 90 and 120 min after repeated ethanol injection (Fig. 6). This association has
also been described in rats, because the M520 strain that is initially
more sensitive to acute alcohol incoordinating effects becomes less
sensitive than the MR strain after repeated alcohol exposure
(Tabakoff and Culp, 1984). This relationship was not found to be
significant for the male mice in our study. The sensitivity appears to
be the response to ethanol most strongly associated with ethanol
preference in
A2AR/ and
A2AR+/+ mice.
Differences in initial sensitivity and/or acute tolerance have also
been described in alcohol-preferring C57BL/6J and
non-alcohol-preferring DBA mouse strains (Tabakoff and Ritzmann,
1979).
In summary, we show that the A2AR is involved in
the sensitivity to the hypothermic and sedative effects of ethanol and
may play a role in alcohol-drinking behavior. The present results further support that the sensitivity to ethanol is a good predictive parameter for the development of alcohol dependence. The exact role of
A2AR in this relationship needs additional
investigation. It is clear that the role of the
A2AR in ethanol consumption is complex and may
not be unitary but may possibly involve both interactions with the
dopaminergic reward pathway and anxiety mechanisms.
| |
FOOTNOTES |
Received July 15, 2002; revised Sept. 3, 2002; accepted Sept. 18, 2002.
This work was supported by Conseil Régional de Picardie (Fonds
Européens de Développement Régional) funds. We
thank Stephane Delanaud for his technical assistance.
Correspondence should be addressed to Dr. Mickaël Naassila,
Laboratoire de Physiologie-Alcoologie, Université de Picardie Jules Verne, Faculté de Pharmacie, 1 rue des Louvels, 80000 Amiens, France. E-mail: mickael.naassila{at}u-picardie.fr.
| |
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ABSTRACT
INTRODUCTION
