About Course
Chapter 8. Neurobiology of Alcohol
NEUROBIOLOGY OF ALCOHOL: INTRODUCTION
Ethanol is a small molecule that readily distributes into highly perfused tissues such as the brain.
Peak levels of ethanol are attained approximately 30 minutes after ingestion of an alcoholic drink.
A single drink of ethanol produces a biphasic effect with a rapid stimulatory phase associated with
an increase in blood ethanol concentrations followed by a depressant phase as the blood
concentration diminishes. Although the ethanol from a single drink is readily metabolized in two
steps involving the enzymes alcohol dehydrogenase and aldehyde dehydrogenase, this process
follows zero-order kinetics. Accordingly, there is a decrease in the percentage of ethanol
metabolized per given unit of time, as the dose of this agent is increased.
Because of its comparatively low toxicity per unit volume, ethanol can be consumed in large
amounts and, consequently, individuals with impaired control over their drinking may remain
highly intoxicated for extended periods. Serious disruption in the performance of many of the
activities of daily living can occur as a result of the behavioral disinhibition and impairments of
judgment, cognition, and fine motor skills associated with high levels of intoxication. Repeated
exposure to ethanol is associated with the development of tolerance to many of its effects. The
continual use of ethanol can also lead to the development of physical dependence and the
consequent onset of withdrawal symptoms following the discontinuation of ethanol consumption.
When compared with most pharmacological agents, the potency of ethanol is extremely low, with
its effects becoming apparent only in the millimolar range. Most drugs, in contrast, are active at
micromolar or even nanomolar concentrations. The low potency of ethanol raises questions as to
the specificity of its actions. The effects of ethanol on behavior appear to be mediated by its effects
on a variety of proteins in the nervous system. These include proteins associated with
-aminobutyric acid (GABA)A receptors, the glutamate receptors (including the
N-methyl-D-aspartate [NMDA], -amino-3-hydroxy-5-methylisoxazole-4-propionic acid [AMPA],
and kainate receptors), nicotinic receptors, cannabinoid CB1 receptors, voltage-gated calcium ion
channels, and calcium-activated potassium (BK) channels. The exact nature of the interaction of
ethanol with these proteins largely remains to be elucidated. There is limited evidence, however,
that ethanol may interact with specific amino acids at discrete locations on the sequence of amino
acids that form NMDA receptors (Honse et al. 2004; Smothers and Woodward 2006), the adenylyl
cyclase enzyme (Yoshimura et al. 2006), and possibly a particular subunit of the GABAA receptor
(Jung and Harris 2006).
Some authors have stressed the relationship between blood alcohol concentrations and the effects
of ethanol on specific neuronal systems in the brain as a key to understanding the behavioral
effects of ethanol (Wallner et al. 2006). The behavioral effects correlate with the concentration of
ethanol achieved in the brain, which is directly related to blood alcohol concentration. Mild
intoxication produced by the consumption of one or two standard drinks (a standard drink is a glass
of wine, a bottle of beer, or a shot of spirits) occurs with ethanol levels of 5–10 mmol/L and may
involve mild disruption of cognitive processing and mood changes, ranging from mild mood
elevation to dysphoria. Moderate drinking leads to ethanol concentrations as high as 20 mmol/L;
however, the legal limit for driving is now frequently set at blood levels of 17 mmol/L (0.08
mg/dL). Ethanol levels greater than 100 mmol/L may produce coma and death. Ethanol
concentrations in the range of 10–50 mmol/L might be most relevant in the identification of
proteins that mediate the actions of ethanol in all but the most severe states of intoxication. In
many studies, ethanol concentrations greater than 100 mmol/L have been used to assess thePrint: Chapter 8. Neurobiology of Alcohol http://www.psychiatryonline.com/popup.aspx?aID=345891&print=yes…
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effects of ethanol on receptors and ion channels. This has led some investigators to question
certain claims that have been made in the past concerning the effects of ethanol on GABA and other
neurotransmitter systems (Krystal et al. 2006).
Recent evidence indicates that even small doses of ethanol (0.25–0.5 g/kg) can substantially
reduce glucose metabolism in the brain without producing detectable alterations in cognitive
performance (Volkow et al. 2006). The full implications of ethanol-induced alterations in brain
metabolism on neuronal function have still not been fully characterized. Chronic ethanol use
appears to have effects on glucose utilization that are evident during the detoxification of alcoholic
individuals. Volkow et al. (1994) showed that glucose metabolism in several brain regions,
including the frontal cortex, orbitofrontal cortex, and basal ganglia, was lower at the start of
detoxification of alcohol-dependent individuals than in control subjects. Over the course of a
30-day withdrawal period, glucose metabolism increased in frontal regions; however, metabolism
was found to remain lower than control levels in the basal ganglia.
Supported by National Institute on Alcohol Abuse and Alcoholism grant K24 AA13736 (Kranzler).
CAMP PATHWAYS
The second messenger cyclic adenosine monophosphate (cAMP) plays a key role in the regulation
of cellular activity by acting through cAMP-dependent protein kinase A (PKA) to phosphorylate a
host of proteins, including those that regulate gene expression, receptor function, and ion channel
function. The activation of G protein–coupled receptors can elevate or decrease intracellular
concentrations of cAMP by altering activity of the different types (isoforms) of adenylyl cyclase.
Alterations of cAMP levels within the cell, in turn, modulate PKA activity. PKA is composed of
different regulatory and catalytic subunits. Ethanol administration can enhance the activity of some
isoforms of adenylyl cyclase (Tabakoff and Hoffman 1998; Yoshimura et al. 2006) that have been
shown to enhance PKA activity (Ortiz et al. 1995). Recent abstinence from ethanol is associated
with a decrease in platelet adenylyl cyclase activity, but increases in the activity of these enzymes
occur in association with a history of alcohol dependence (Hoffman et al. 2002).
The selective deletion of the PKA regulatory RII subunit from mice resulted in an increase in
ethanol consumption and a decrease in the sedative effects of ethanol (Thiele et al. 2000b).
Infusion of a PKA inhibitor, Rp-cAMP, into the nucleus accumbens (NAcc) elevated ethanol intake in
rats (Misra and Pandey 2005). This inhibitor also reduced levels of the phosphorylated form of the
gene transcription factor, cAMP response element–binding protein (CREB), and protein levels of
neuropeptide Y (NPY) in the NAcc. This may be of significance because both CREB and NPY have
been implicated in the regulation of ethanol consumption (Hayes et al. 2005; Misra and Pandey
2003; Pandey et al. 2004). In mice that were haplodeficient for CREB (i.e., those with partial
deletion of the CREB gene), ethanol consumption increased (Pandey et al. 2004). These mice
showed decreased levels of phosphorylated CREB and expression of NPY in brain structures that
include the amygdala, hippocampus, and NAcc (Pandey et al. 2004).
Ethanol-induced PKA activity may have broad influences on neuronal function, many of which are
presently poorly understood. NMDA receptor function varies with the phosphorylation state of the
receptor, and PKA plays a major role in this variation. Activation of dopamine D1 receptors can
enhance the activity of PKA, which then leads to enhanced phosphorylation of CREB. The alteration
of CREB activity not only appears to influence the regulation of ethanol consumption but has also
been implicated in the reinforcing actions of many other abused substances, including cocaine and
morphine (McClung and Nestler 2003; Walters and Blendy 2001).
NEUROTRANSMITTER SYSTEMS AND ETHANOL
Dopamine
Dopaminergic neurons in the mesolimbic region project from the ventral tegmental area (VTA) to
the NAcc. The NAcc may be crucially important in producing the rewarding actions of ethanol
(Weiss and Porrino 2002). Ethanol administration enhances dopamine release in the NAcc (DiPrint: Chapter 8. Neurobiology of Alcohol http://www.psychiatryonline.com/popup.aspx?aID=345891&print=yes…
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Chiara and Imperato 1988; Yim and Gonzales 2000), which may result from ethanol-induced
increases in the firing rate of dopamine cells located in the VTA (Brodie et al. 1999; Gessa et al.
1985). The repeated administration of ethanol may result in sensitization of dopamine VTA neurons
to the effects of ethanol on dopamine cell firing (Brodie 2002). However, during acute withdrawal
from ethanol, spontaneous activity of dopamine cells in the VTA is decreased (Shen and Chiodo
1993), as is dopamine release in the NAcc (Weiss et al. 1996).
Dopamine D2 receptor–deficient mice, “knockout mice,” show less preference for ethanol than do
the wild-type mice that can express this receptor (Thanos et al. 2005b). Transfer of D2 receptor
deoxyribonucleic acid (DNA) by viral vector into the NAcc of mice lacking this receptor leads to an
increase in ethanol consumption and preference. In contrast, transfer of D2 receptor DNA into
wild-type mice and mice heterozygous for the D2 receptor gene reduces ethanol consumption.
These results suggest that the D2 receptor regulates ethanol drinking and that either high or
minimal receptor availability is associated with reduced levels of drinking.
There is some evidence that low D2 availability in the striatum may be related to alcohol use
disorders. Volkow et al. (2002) have shown that subjects with early-onset alcohol dependence have
lower D2 availability in the caudate and putamen than do control subjects. Individuals with alcohol
use disorders have also been shown to have lower D2 receptor levels in the ventral striatum than
do controls (Heinz et al. 2004). D2 receptor concentrations in the ventral striatum have been found
to correlate negatively with both alcohol craving and ethanol cue-induced activation of the medial
prefrontal cortex and the anterior cingulate (Heinz et al. 2004).
Serotonin
In monkeys, high rates of ethanol consumption are associated with low cerebrospinal fluid (CSF)
levels of the serotonin metabolite 5-hydroxyindoleacetic acid (5-HIAA) (Higley et al. 1996).
Evidence implicating serotonin in the development of alcoholism includes the observation that
concentrations of 5-HIAA in CSF may be lower in early-onset alcoholic individuals than in those
whose alcohol use disorders had a late onset (Fils-Aime et al. 1996).
Extracellular serotonin levels are regulated by the activity of serotonin transporters, which mediate
the reuptake of this neurotransmitter into presynaptic neurons. Studies in rodents indicate that
ethanol administration may lead to significant elevations in serotonin levels in the hippocampus
(Daws et al. 2006) and striatum (Thielen et al. 2001). However, evidence from mutant mouse
models suggests that the effects of ethanol on serotonin levels in the hippocampus may not result
from a direct interaction of alcohol with serotonin transporters (Daws et al. 2006).
The availability of brainstem serotonin transporter sites, as labeled by the radioligand [I-123]2
-carbomethoxy-3 -(4-iodophenyl) tropane ([I-123] -CIT), was found to correlate positively with
the mean daily intake of ethanol by monkeys (Heinz et al. 2003). Binding of ligands to serotonin
transporters, however, was reduced in the brainstem of alcoholic individuals (Heinz et al. 1998;
Szabo et al. 2004) and in other regions, including the frontal cortex, midbrain, thalamus, and
amygdala (Szabo et al. 2004). However, Brown et al. (2007) showed that when a new
radioligand—[11C]-3-amino-4-(2-dimethylaminomethylphenylsulfanyl)benzonitrile—with high
specific binding for the serotonin transporter was used, there were no differences in binding to this
transporter protein between alcohol-dependent and control subjects. The extent of binding to
serotonin transporters in the raphe nucleus by [I-123] -CIT was dependent upon the genotype of a
polymorphic site in the promoter of the gene encoding the transporter (Heinz et al. 2000). Studies
that carefully control for genetic factors may be needed to clarify the relationship between
alcoholism and serotonin transporter availability.
Ethanol consumption may also be modulated by the serotonin type 3 (5-HT3) receptor.
Administration of the 5-HT3 antagonist ondansetron results in a reduction of ethanol consumption
by individuals with early-onset alcoholism (Johnson and Ait-Daoud 2000; Kranzler et al. 2003). The
administration of 5-HT3 antagonists, including ondansetron, also reduced ethanol intake in animals
(Tomkins et al. 1995). This effect is not seen when a 5-HT3 antagonist is administered to mice thatPrint: Chapter 8. Neurobiology of Alcohol http://www.psychiatryonline.com/popup.aspx?aID=345891&print=yes…
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are missing the gene for the 5-HT3A receptor subtype (Hodge et al. 2004). Infusion of the 5-HT3
antagonist tropisetron into the NAcc reduces ethanol-induced increases in dopamine release
(Yoshimoto et al. 1992) and ethanol consumption (Jankowska and Kostowski 1995). This suggests
5-HT3 receptors may modulate ethanol drinking via an action on dopamine release in the NAcc.
There is some evidence that 5-HT1B receptors can modulate the dopamine-releasing actions of
ethanol. Results of a study by Yan et al. (2005) suggest that infusion of 5-HT1B receptor agonists
into the VTA significantly prolong the time during which ethanol administration produces an
increase in dopamine levels in the NAcc. In contrast, their findings indicate that ethanol-induced
dopamine release is decreased by the intrategmental infusion of 5-HT1B antagonists. In animal
models of alcohol consumption, the administration of serotonin 5-HT1B receptor agonists can
suppress ethanol intake (Higgins et al. 1992; Tomkins and O’Neill 2000). Rats consume more
ethanol after being given an injection of a viral vector containing 5-HT1B DNA, which increases the
expression of 5-HT1B receptors in the NAcc (Hoplight et al. 2006). However, the effects of deletion
of 5-HT1B receptors from mice have been inconsistent. Some investigators (Crabbe et al. 1996), but
not others (Gorwood et al. 2002), have found that 5-HT1B knockout mice consumed more ethanol
than wild-type mice. Although these findings suggest that 5-HT1B receptors may play a role in
modulating ethanol self-administration, it is unclear how expression levels of 5-HT1B receptors are
related to this effect.
Nicotinic Receptors
The stimulant effects of ethanol are attenuated in healthy subjects who have been pretreated with
the nicotinic receptor antagonist mecamylamine (Blomqvist et al. 2002). This finding complements
those from animal studies that implicate nicotinic receptors in the mediation of the actions of
ethanol. In animals, the systemic administration of mecamylamine may decrease ethanol-induced
enhancement of locomotor activity (Blomqvist et al. 1992) and suppresses voluntary ethanol
consumption (Blomqvist et al. 1996). When infused into the VTA, mecamylamine may block
ethanol-induced dopamine release in the NAcc (Blomqvist et al. 1997; Tizabi et al. 2002) and may
also reduce ethanol consumption (Ericson et al. 1998). The voluntary intake of ethanol produces an
increase in acetylcholine levels in the VTA, an effect that may explain how ethanol may activate
nicotinic receptors in the VTA that regulate dopamine release in the NAcc (Larsson et al. 2005).
In addition to acting on nicotinic receptors by enhancing acetylcholine release, ethanol may also
have more direct effects on these receptors (Aistrup et al. 1999). Ethanol, through actions on
presynaptic nicotinic receptors, may enhance the release of GABA (Alkondon et al. 1997; Moriguchi
et al. 2007). Potential implications of this effect are discussed in the section after next, “GABAA
Receptor Systems.” Nicotinic receptors consist of different combinations of subunits, and the
precise subunit combination may determine the nature of the receptor response to ethanol
(Cardoso et al. 1999; Covernton and Connolly 1997). Nicotinic receptors containing 3 4 subunits
are either inhibited or potentiated by low concentrations of ethanol (Covernton and Connolly 1997).
Deletion of the 7 nicotinic subunit from mice increases their sensitivity to the hypnotic effects of
ethanol (Bowers et al. 2005). Even slight variations in the amino acid composition of the 4 subunit
may determine the extent to which 4 2-containing nicotinic receptors are activated by ethanol
(Butt et al. 2003). This suggests that genetic polymorphisms in nicotinic receptors may help
determine how individuals differ in their responses to ethanol.
Cannabinoid CB1 Receptors
The activation of cannabinoid CB1 receptors may promote the release of dopamine in the NAcc by
increasing firing rates of dopamine neurons in the VTA (Gessa et al. 1998; Tanda et al. 1997). The
administration of the CB1 receptor antagonist rimonabant blocks ethanol-induced firing of
tegmental dopaminergic neurons (Perra et al. 2005). This compound also inhibits
ethanol-stimulated dopamine release in the NAcc (Cheer et al. 2007). Administration of rimonabant
significantly reduces the intake of ethanol in wild-type mice, but not in mice in which the CB1
receptor is deleted (Thanos et al. 2005a). Compared with the ethanol consumption of wild-typePrint: Chapter 8. Neurobiology of Alcohol http://www.psychiatryonline.com/popup.aspx?aID=345891&print=yes…
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mice, the ethanol consumption of mutant mice whose CB1 receptor has been deleted is significantly
reduced (Thanos et al. 2005a). These results suggest that the CB1 receptor may regulate the
rewarding actions of ethanol as part of the regulatory actions of CB1 receptor systems within the
mesolimbic system.
GABAA Receptor Systems
Many of the behavioral effects of ethanol appear to result from its interaction with GABAA
receptors. Barbiturates and benzodiazepines positively modulate the actions of GABA at these
receptors. These agents have several behavioral effects that parallel those of ethanol, including
anxiolytic, anticonvulsant, hypnotic, and sedative actions. Injection of the GABAA receptor agonist
muscimol into limbic areas produces stimulus properties that substitute for those of ethanol in drug
discrimination studies (Hodge and Alken 1996). The sedative and motor-impairing effects of
ethanol are potentiated by the concurrent administration of either GABAA receptor agonists, such
as muscimol, or positive modulators of the GABAA receptors, such as the benzodiazepines (Frye and
Breese 1982; Martz et al. 1983; Tauber et al. 2003). The administration of benzodiazepine inverse
agonists will block or reverse the depressant effects of ethanol, as well as suppress its
self-administration (Petry 1995; Suzdak et al. 1986). Sedation produced by the infusion of ethanol
into the brain is blocked by the administration of the GABAA receptor antagonist bicuculline (Givens
and Breese 1990). The hyperexcitability associated with withdrawal from chronic ethanol exposure,
including seizures, can be reversed or attenuated by the administration of benzodiazepines. Finally,
there is cross-tolerance of benzodiazepines or barbiturates to the depressant effects of ethanol
(Khanna et al. 1998).
Behavioral studies can only provide indirect evidence that ethanol interacts with GABAA receptor
systems. A large body of physiological and biochemical studies has examined the interactions
between ethanol and GABAergic systems. GABAA receptors consist of a family of structurally
related ionotropic receptors. This family includes a variety of pentameric complexes consisting of
subunits that differ in their amino acid structure. Common subunits found to exist in the brain
include the types (including subtypes 1, 2, 4, and 6), (subtypes 2 and 3), , and (subtypes 1,
2, and 3). The most abundant GABAA receptors identified in the brain consist of two , two , and
one subunit (Pritchett et al. 1989). GABAA receptors containing the 1 subunit may mediate the
sedative-hypnotic actions of benzodiazepines and new hypnotic agents, such as zolpidem (Blednov
et al. 2003). The presence of 2 subunits in GABAA receptors has been linked to the mediation of
the anxiolytic effects of the benzodiazepines (Morris et al. 2006). Deletion of the 1 subunit gene
attenuates the sedative actions of ethanol in male mice (Blednov et al. 2003), although this effect
has not been seen in some strains of 1 subunit knockout mice (Kralic et al. 2003). In rats, infusion
of a selective
1 subunit antagonist into the ventral pallidum, which receives extensive output from
the NAcc, blocks both the sedative and reinforcing effects of ethanol (Harvey et al. 2002; June et al.
2003). In humans, genetic variation in the amino acid composition of the 2 subunit has been
associated with differences in the subjective effects of ethanol (Pierucci-Lagha et al. 2005).
GABAA receptors containing 1 x 2 subunit combinations are abundant in the postsynaptic sites of
the brain and exhibit sensitivity to benzodiazepines. Of these, the 1 2 2 combination binds readily
to zolpidem, and brain sites that show dense binding of zolpidem have been linked to the actions of
ethanol (Criswell et al. 1993, 1995). Whether ethanol interacts directly with postsynaptic GABAA
receptors at concentrations that produce moderate levels of intoxication has been questioned
because several studies have shown that ethanol enhances the activity of GABAA receptors only at
concentrations associated with extremely high levels of intoxication (Krystal et al. 2006). An
alternative mechanism through which ethanol may indirectly interact with GABAA receptors may
involve the process of alcohol-evoked GABA release. Acute ethanol administration increases the
release of GABA from presynaptic sites in some brain regions, including the central nucleus of the
amygdala, a structure implicated in the rewarding effects of ethanol (Siggins et al. 2005).
Electrophysiological data also suggest that ethanol can promote GABA release in the cerebellum
(Carta et al. 2004). In some regions, such as the hippocampus, this effect may be regulated byPrint: Chapter 8. Neurobiology of Alcohol http://www.psychiatryonline.com/popup.aspx?aID=345891&print=yes…
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presynaptic GABAB receptors, which may limit GABA release as part of a negative feedback system.
A second mechanism through which ethanol may interact with GABAA receptors is by increasing
neurosteroid concentrations in the brain (Morrow et al. 1999). Neurosteroids, such as
allopregnanolone, are synthesized in the brain from cholesterol (Hu et al. 1987). They may increase
the activity of GABAA receptors by binding to specific sites on the and subunits of these
receptors (Hosie et al. 2006). The acute administration of ethanol can increase concentrations of
allopregnanolone in the plasma, cerebral cortex, and hippocampus (Barbaccia et al. 1999; Morrow
et al. 2001; VanDoren et al. 2000). This may occur through the stimulation of neurosteroid
synthesis, an effect that may, at least in part, involve the effects of ethanol on the
hypothalamic-pituitary-adrenal (HPA) axis (Follesa et al. 2006). In humans, the administration of
finasteride, a compound that inhibits neurosteroid synthesis, attenuates the subjective effects of a
moderate dose of ethanol (Pierucci-Lagha et al. 2005).
GABAA receptors containing 4 3 , 6 3 , and 4 2 subunit combinations have been shown by
some investigators to be sensitive to the effects of low concentrations of ethanol
(Sundstrom-Poromaa et al. 2002; Wallner et al. 2003), though in a recent study this effect could
not be replicated for the 4 3 subunit combination (Borghese et al. 2006). GABAA receptors
containing subunits and either 4 or 6 subunits have extrasynaptic locations and regulate tonic
(rather than phasic) currents (Hanchar et al. 2004). These extrasynaptic receptors represent a
smaller proportion of GABAA receptors in the brain than do those located in the synapse. Receptors
containing the 6 3 combination are present in cerebellar granule cells, whereas those composed
of the 4 3 combination are more widespread in the brain and appear in areas such as the
hippocampus, striatum, and frontal cortex (Wallner et al. 2006). GABAA receptors containing 4 or
6 subunits in combination with the subunits may mediate the anxiolytic motor coordination,
impairment, and the sedative effects of low-dose ethanol.
Prolonged exposure to ethanol may result in decreased sensitivity (i.e., tolerance) to the sedative
and many other actions of ethanol. Tolerance to the action of ethanol may occur in association with
a decrease in GABAA-mediated function (Grobin et al. 1998). Acute forms of tolerance to the
sedative-hypnotic effects of ethanol, which occur in a single drinking session, may be related to the
phosphorylation of the isoform of protein kinase C (PKC) (Wallace et al. 2007). Chronic tolerance,
it has been suggested, may result from an alteration in the subunit composition of GABAA receptors
that are present in the brain. Such changes in subunit expression are seen in animal studies that
either examined the presence of subunit proteins by immunoreactivity or measure levels of
messenger ribonucleic acids (mRNAs), which are responsible for the synthesis of the subunits
(Grobin et al. 1998; Mahmoudi et al. 1997). These changes include a decrease in the expression of
2 subunits in the cerebral cortex and the cerebellum, and an increase in 4, 6, and 1–3 subunits
in these regions. This pattern of change, however, has not been detected for humans with a history
of alcoholism. Evidence concerning the effects of chronic ethanol use on the relative amounts of
different GABAA subunits in the human brain is not consistent. One group of researchers has
reported that levels of mRNA for the 3 receptor subunit may be increased in the frontal cortex of
alcoholic individuals (Mitsuyama et al. 1998). Another group found increases in the 1 subunit
levels in this region (Lewohl et al. 1997) but failed to see this change when tissue from the
superior frontal cortex of noncirrhotic alcoholic patients was examined (Lewohl et al. 2001). In
another study, levels of 2 subunit mRNAs were decreased in the superior frontal cortex (Lewohl et
- 2000). Some researchers, however, have been unable to find changes in the frontal cortex in the
expression of mRNA for any GABAA receptor subunits (Flatscher-Bader et al. 2005; Mayfield et al.
2002).
The significance of findings on the nature of GABAA subunit expression in alcoholic individuals is
confounded by postmortem studies in which investigators are unable to control for genetic
differences between control and alcoholic groups, and variables such as between-group differences
in the cause of death and the state of health before death. Examination of the effects of chronic
ethanol on GABAA subunit expression in nonhuman primates allows for the control of some of these
confounding factors. Chronic self-administration of ethanol decreased the expression of 2, 4, 1, Print: Chapter 8. Neurobiology of Alcohol http://www.psychiatryonline.com/popup.aspx?aID=345891&print=yes…
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3, 1, 2, and 3 subunit mRNAs in the orbital frontal cortex of cynomolgus monkeys (Hemby et al.
2006). In the dorsolateral prefrontal cortex of these animals, mRNAs were decreased for 1, 2, 1,
and subunits, although no changes were observed for subunits in the anterior cingulate. These
reductions in GABAA subunits may contribute to the tolerance that develops to ethanol’s effects.
Tolerance to the effects of ethanol may also be related to alterations in the trafficking of GABAA
receptor subunits between the cell membrane surface and the interior of the cell. This is evidenced
by the finding that chronic exposure to ethanol enhances the internalization of 1 subunits in
cerebral cortical neurons (Kumar et al. 2003).
Glutamate Receptor Systems
NMDA receptors
Activation of NMDA receptors by glutamate and other excitatory amino acids enhances calcium and
sodium flow into neurons, with a resultant increase in excitatory postsynaptic potentials. NMDA
receptors contain four subunits: two NR1 and two NR2 subunits. NR2A and NR2B subtypes exist,
and, in some cases, other subunits, such as the NR3 subunit, may also be present. Glutamate may
activate NMDA receptors by binding to the NR2 or comparable subunit. The functioning of NMDA
receptors is dependent on the binding of the amino acid glycine to the NR1 subunit. NMDA
receptor–mediated flux is regulated by a voltage-dependent magnesium block. Consequently, these
receptors become active only when a certain level of neuronal depolarization is reached.
Competitive antagonists directly block the binding of glutamate to the NMDA receptor. Ketamine,
phencyclidine, and many other agents act as uncompetitive antagonists at the NMDA receptor by
binding to sites within the ion channel of the receptor complex.
Several studies indicate that there is overlap in the stimulus properties of ethanol and
uncompetitive NMDA receptor antagonists (Hodge et al. 2001; Hölter et al. 2000; Hundt et al.
1998). In animal studies, the administration of both competitive and uncompetitive antagonists
reduces responding for ethanol (Rassnick et al. 1992; Shelton and Balster 1997). However, these
agents will also reduce responding for saccharin solutions, which argues against the specificity of
their actions (Shelton and Balster 1997). The administration of both uncompetitive and competitive
NMDA receptor antagonists decreases ethanol consumption at doses that produced only small
changes in food intake (McMillen et al. 2004), which is consistent with the idea that NMDA
receptors regulate ethanol consumption.
From a functional standpoint, acute ethanol administration appears to inhibit NMDA receptor
activity. At concentrations as low as 10 mmol/L, ethanol can inhibit NMDA receptor–mediated
influx of calcium in cultured cerebellar granule cells (Hoffman et al. 1989). The acute
administration of ethanol may reduce excitatory postsynaptic potentials mediated by NMDA
receptors in the hippocampus (Lovinger et al. 1989, 1990), with significant inhibition being
detected at an ethanol concentration of 25 mmol/L. In the core of the NAcc, NMDA currents are
reduced by ethanol at concentrations ranging between 11 and 200 mmol/L (Nie et al. 1994).
Ethanol in concentrations of 25–75 mmol/L inhibits NMDA excitatory postsynaptic potentials in
medium spiny neurons of the shell of the NAcc (Zhang et al. 2005). There is limited evidence that
the inhibitory effects of ethanol are regulated by discrete sites located on NR1 (Smothers and
Woodward 2006) and NR2A (Honse et al. 2004) subunits.
The sensitivity of NMDA receptors to glutamate and other agonists is regulated by the
phosphorylation and dephosphorylation of receptor subunits. Kinases, such as PKA and tyrosine
kinases, phosphorylate the receptor, whereas phosphatases, such as PP1, can dephosphorylate the
receptor. The hypnotic effect of ethanol is greatly enhanced in mutant mice with deletions of the
gene for Fyn-tyrosine kinase (Miyakawa et al. 1997; Yaka et al. 2003). However, presence of the
Fyn mutation does not appear to alter voluntary ethanol consumption (Yaka et al. 2003). The NR2B
subunit may be a target of Fyn-tyrosine phosphorylation. Involvement of this subunit in mediating
ethanol’s sedative effects is suggested by the finding that the administration of ifenprodil, a
selective antagonist of the NR2B subunit, increases the duration of loss of the righting reflex inPrint: Chapter 8. Neurobiology of Alcohol http://www.psychiatryonline.com/popup.aspx?aID=345891&print=yes…
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wild-type mice (Yaka et al. 2003).
The presence of a dopamine D1 receptor agonist leads to a marked reduction in the inhibitory
actions of ethanol on NMDA-induced currents in the NAcc (Maldve et al. 2002). This may result
from D1 receptor–mediated phosphorylation of the NR1 subunit. In cAMP-regulated phosphoprotein
32KD (DARPP-32) knockout mice, D1 agonist stimulation fails to alter the sensitivity of NMDA
receptors to the inhibitory effects of ethanol (Maldve et al. 2002). The reinforcing effects of ethanol
are attenuated in DARPP-32 knockout mice (Risinger et al. 2001), which may indicate that
DARPP-32–mediated phosphorylation of the NMDA receptor is involved in the neuroadaptation that
promotes ethanol consumption.
NMDA receptors may be up-regulated during ethanol withdrawal (Haugbøl et al. 2005). In the
amygdala, chronic ethanol treatment produces an increase in NMDA-stimulated currents, possibly
indicating that NMDA receptor up-regulation is related to enhanced sensitivity of the NMDA
receptor systems (Floyd et al. 2003). Treatment with NMDA receptor antagonists such as
memantine reduces ethanol withdrawal seizures, suggesting a role for the NMDA receptor in the
onset of withdrawal symptoms (Bienkowski et al. 2001).
Chronic ethanol administration increases mRNA and protein levels for NMDA receptor subunits in
various brain regions, including the amygdala, cerebellum, frontal cortex, and hippocampus
(Darstein et al. 2000; Floyd et al. 2003; Kalluri et al. 1998). Similarly, in postmortem tissues, there
is greater density of putative NMDA receptor binding sites in frontal cortical tissues obtained from
alcoholic individuals than from controls (Freund and Anderson 1996). In rats treated chronically
with ethanol, concentrations of NMDA receptor subunits in the cerebral cortex and hippocampus
returned to near-control levels 48 hours after the start of withdrawal (Kalluri et al. 1998). Chronic
ethanol exposure increases the size and density of clusters of the NR1 and NR2B subunits in
synapses of hippocampal neurons (Carpenter-Hyland et al. 2004). Thus, chronic ethanol
administration appears to remodel the pattern of distribution of synaptic NMDA receptor subunits in
neurons.
A recent study by Zhou et al. (2007) indicates that, in addition to altering NMDA subunit expression
and NMDA receptor function, chronic ethanol administration may also alter the structure of
dendritic spines within the NAcc. Both continuous and intermittent access to ethanol reduced
dendritic spines of medium spiny neurons of the NAcc. Intermittent ethanol exposure was
associated with the appearance of large-sized spines. Continuous access to ethanol was also
associated with an up-regulation of NR1 subunits. Ethanol-induced alterations in dendritic spine
morphology may be related to changes in the postsynaptic proteins that regulate NMDA receptor
function. These proteins include Homer and Shank, which are involved in the anchoring of NMDA
receptors and regulate their function. Deletion of the Homer-2 protein in mice enhanced the
hypnotic effects of ethanol and increased place aversion to environments associated with ethanol
administration (Szumlinski et al. 2005).
Ethanol exposure may also alter the function of NMDA receptors by changing the trafficking of
NMDA receptor subunits. Treatment with ethanol increases the internalization of NR2A subunits
into hippocampal neurons. This, in turn, produces NMDA receptors that consist predominantly of
NR2B subunits, which are associated with the form of synaptic plasticity known as long-term
depression, which plays a role in memory (Liu et al. 2004).
The up-regulation of NMDA receptors that results from chronic ethanol exposure may be one factor
that contributes to the increased neuronal excitability that occurs during withdrawal from ethanol.
A second factor in the development of hyperexcitability during withdrawal may be increased
extracellular levels of excitatory amino acids in the brain. Glutamate may be elevated in both the
hippocampus (Dahchour and De Witte 2003) and the striatum (Rossetti and Carboni 1995;
Saellstroem et al. 2006) during ethanol withdrawal. These elevations may involve positive feedback
loops in which glutamate stimulates NMDA receptors to facilitate further release of this amino acid
(Rossetti et al. 1999). Interestingly, nicotine administration also increases glutamate release in the
NAcc in animals withdrawn from ethanol (Saellstroem et al. 2006).Print: Chapter 8. Neurobiology of Alcohol http://www.psychiatryonline.com/popup.aspx?aID=345891&print=yes…
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AMPA/Kainate receptors
AMPA and kainate receptors are glutamate-activated receptors (GluRs) that regulate sodium
currents and in some cases also calcium currents. These receptors overlap in their sensitivity to
certain agonists, but are composed of distinct subunits, with GluR1–4 units forming the AMPA
receptors and GluR5–7 forming the kainate receptors in combination with kainic acid (KA) 1–2
subunits (Dingledine et al. 1999). Ethanol reduces non–NMDA glutamate receptor–mediated
currents in the central nucleus of the amygdala (Zhu et al. 2007). These currents are increased by
the repeated administration of ethanol. In the core of the NAcc, ethanol slightly reduces
kainate-induced currents but has no effect on AMPA-induced currents (Nie et al. 1994). In the
hippocampus, ethanol potently inhibits currents produced by kainate receptors, but not those
associated with the activation of AMPA receptors (Carta et al. 2003).
Although ethanol has not been shown to alter the activity of AMPA receptor systems, these
systems, nevertheless, may play a role in alcoholism. The AMPA receptor subunits GluR2 and GluR3
are elevated in tissues obtained from individuals with a history of alcohol abuse, when compared
with control subjects (Breese et al. 1995). Topiramate, which has AMPA/kainate-blocking
properties (Gryder and Rogawski 2003; Poulsen et al. 2004), reduces ethanol consumption in
alcohol-dependent individuals (Johnson et al. 2003). It is unknown whether this effect involves
actions at kainate receptors, AMPA receptors, or both types of receptor.
AMPA receptor systems may regulate ethanol-seeking behaviors. Reinstatement of responding for
ethanol, a measure of the motivation to seek ethanol, is blocked by the administration of an
AMPA/kainate receptor antagonist (Bäckström and Hyytiä 2004; Sanchis-Segura et al. 2006).
Reinstatement responding induced by ethanol-related cues is blunted in mice missing the GluR3
subunit (Sanchis-Segura et al. 2006). Mice missing this subunit, however, did not differ from
wild-type mice with respect to the self-administration of ethanol.
Metabotropic receptors
Metabotropic receptors are activated by glutamate, but in contrast to glutamatergic ionotropic
receptors, their actions are mediated by G proteins. Group I metabotropic receptors include the
metabotropic GluR1 (mGluR1) and mGluR5 subtypes, and Group II receptors include the mGluR2/3
subtypes. The Group II receptors are located on presynaptic glutamatergic neurons. The Group I
metabotropic receptors and NMDA receptors can each alter the activity of the other receptor type.
For example, activation of NMDA receptors can potentiate the activity of mGluR5 receptors
(Alagarsamy et al. 2005), and NMDA receptor–mediated synaptic transmission is dependent on
activation of mGluR5 receptors (Harney et al. 2006).
Ethanol may decrease the activity of mGluR5-type receptors via a mechanism involving the kinase
PKC (Minami et al. 1998; Netzeband and Gruol 1995). Both the mGluR1 and mGluR5 receptors have
been implicated in the regulation of the rewarding effects of ethanol. The drug acamprosate, which
is approved for the treatment of alcohol dependence, may act as an antagonist at the mGluR5
receptor (Harris et al. 2002). Ethanol-induced elevations of dopamine levels in the NAcc are
blocked by the administration of mGluR1 or mGluR5 antagonists (Lominac et al. 2006). In animal
studies, the administration of mGluR1 and mGluR5 antagonists may reduce ethanol
self-administration (Cowen et al. 2005; Lominac et al. 2006), although mGluR1 antagonists have
not consistently had this effect (Hodge et al. 2006; Schroeder et al. 2005). The mGluR5 antagonist
6-methyl-2(phenylethynyl) pyridine alters ethanol intake in wild-type mice but not in animals in
which the isoform of PKC has been deleted (Olive et al. 2005). This is consistent with other
findings implicating PKC-mediated phosphorylation in the inhibitory actions of ethanol on mGluR5
receptors (Minami et al. 1998).
Neuropeptides
Opioid receptor systems
The endogenous opioid system plays a role in the reinforcing effects of ethanol and a variety ofPrint: Chapter 8. Neurobiology of Alcohol http://www.psychiatryonline.com/popup.aspx?aID=345891&print=yes…
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other drugs that are self-administered by animals and abused by humans, including nicotine,
cocaine, amphetamines, and cannabinoids. Three classes of opioid receptors, , , and , interact
with opioid peptides to produce their biological effects (Kieffer 1995). The opioid receptor
mediates the effects of morphine and related opioid agonists (Yu 1996). It has a putative
secondary structure of seven transmembrane domains common to G protein–coupled receptors,
with functional coupling to adenylyl cyclase.
Ethanol, like nicotine, cocaine, amphetamines, and cannabinoids, releases dopamine in the NAcc (Di
Chiara and Imperato 1988; Tanda et al. 1997). In addition, opioid receptors in the VTA modulate
NAcc dopamine activity and ethanol-preferring (AA) rats have a significantly higher density of
opioid receptors in the VTA (and related limbic brain regions) than ethanol-avoiding (ANA) rats (De
Waele et al. 1995).
The opioid receptor is also a G protein–coupled receptor with functional coupling to adenylyl
cyclase, and it too has been shown to modulate ethanol consumption (Froehlich et al. 1991;
Krishnan-Sarin et al. 1995). In rats selectively bred for high levels of ethanol drinking, the selective
antagonist ICI 174864 was found to be more potent than naloxone in suppressing ethanol
consumption (Froehlich et al. 1991; Krishnan-Sarin et al. 1995). The more highly selective and
longer-acting antagonist, naltrindole hydrochloride, also produced a dose-dependent suppression
of drinking in rats selectively bred for ethanol consumption (Krishnan-Sarin et al. 1995).
In research done by Gianoulakis and Gupta (1986), concentrations of endogenous opioids, which
bind to and opioid receptors, are correlated with ethanol exposure. Acute ethanol treatment of
ethanol-drinking mice increased the hypothalamic release of -endorphin. In humans, individuals
with alcohol use dependency showed decreased basal plasma (Aguirre et al. 1990) and CSF
(Genazzani et al. 1981) concentrations of -endorphin. Furthermore, nonalcoholic adults with a
family history of alcoholism (i.e., high risk) had basal concentrations of -endorphin that were
comparable with those of abstinent alcoholic persons but significantly lower than those of low-risk
individuals (Gianoulakis et al. 1989). Following ethanol administration, -endorphin levels
increased among high-risk subjects, resulting in levels comparable with those seen following
ethanol administration among low-risk subjects (Gianoulakis et al. 1989). Furthermore, ethanol
induced a dose-dependent increase in plasma -endorphin levels in high-risk but not low-risk
subjects (Gianoulakis et al. 1996).
Enkephalins may also play a role in the reinforcing effects of ethanol (Li et al. 1998; Mendez and
Morales-Mulia 2006). The efficacy of opioid antagonists (i.e., naltrexone, nalmefene) in the
treatment of alcoholism (Srisurapanont and Jarusuraisin 2005) provides further evidence that the
rewarding properties of ethanol are, in part, mediated by the opioid system.
Neuropeptide Y
NPY is a 36-amino acid peptide neurotransmitter. Mice deleted for the gene encoding NPY showed a
preference for drinking ethanol-water solutions over water (Thiele et al. 1998). These mice were
also less sensitive to the hypnotic and sedative effects of ethanol than NPY wild-type mice. In
contrast, mice manipulated to overexpress NPY showed less preference for ethanol and greater
sensitivity to the sedative and hypnotic effects of ethanol (Thiele et al. 1998, 2000a). Studies of
specific NPY receptors show that Y1 receptors inhibit voluntary ethanol consumption and some of
ethanol’s intoxicating effects, such that mice deleted for the gene encoding this receptor show
increases on these measures (Pandey et al. 2003; Thiele et al. 2002). In contrast, the Y2 receptor
serves as a presynaptic autoreceptor that inhibits NPY release, so that mice deleted for the gene
encoding this receptor show reduced ethanol consumption (Pandey et al. 2003). These findings
have led to the suggestion that NPY Y1 agonists and Y2 antagonists may be of value in the
treatment of alcoholism (Cowen et al. 2004).
Other peptide neurotransmitters
Other peptides that have been linked to the actions of ethanol are corticotropin-releasing hormone
(CRH), urocortin, leptin, cholecystokinin, melanocortins, and galanin (reviewed in Cowen et al.Print: Chapter 8. Neurobiology of Alcohol http://www.psychiatryonline.com/popup.aspx?aID=345891&print=yes…
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2004). Preclinical studies have linked the CRH system to the effects of a variety of substances of
abuse, including alcohol (Sarnyai et al. 2001). CRH, which plays a central role in the response to
stress by regulating the HPA axis, exerts its effects through CRH1 and CRH2 receptors. In an acute
free-choice paradigm, Sillaber et al. (2002) found that mice homozygous for a CRH1 receptor gene
deletion (CRH–/–) did not differ from wild-type mice with respect to their consumption of fluids,
including ethanol. However, following habituation to 8% ethanol and exposure to a repeated social
defeat stress, when tested again 3 weeks later, CRH–/– animals consumed more than twice the
volume of ethanol daily that did their wild-type littermates. Although subsequent exposure to a
swim stress slightly decreased ethanol consumption acutely in both groups of animals, CRH–/– mice
subsequently showed increased drinking, whereas there was no increase in drinking among the
wild-type mice. The doubling of ethanol intake persisted among the CRH–/– mice for more than 6
months. The rate of ethanol metabolism did not differ between the groups of mice, excluding this
as a possible explanation for the observed effects on drinking behavior. However, further analysis
did reveal increased expression of the NR2B subunit of the NMDA receptor, without alteration of
the expression of any other ionotropic glutamate subunit.
ETHANOL INTERACTIONS WITH ION CHANNELS
Voltage-gated calcium ion channels regulate neuronal excitability and neurotransmitter release by
regulating calcium flow into neurons in response to membrane potential changes. Several varieties
of voltage-gated calcium channels have been identified, including the L, N, P/Q, R, and T types.
Studies of the effects of ethanol on calcium channels in isolated cell preparations indicate that
ethanol can inhibit the activity of L-type (Mullikin-Kilpatrick and Treistman 1995), N-type (Solem et
- 1997), P/Q-type (Solem et al. 1997), and T-type (Littleton et al. 1992; Mu et al. 2003; Twombly
1990) calcium channels. The functional implication of ethanol’s actions on voltage-gated calcium
channels is just beginning to be characterized. Dihydropyridine-sensitive (L-type) binding sites are
increased in ethanol-dependent rats (Dolin et al. 1987), and L-channel antagonists can prevent
withdrawal symptoms in these animals. N-type and P/Q-type channels have been implicated in the
regulation of neurotransmitter release (Reid et al. 2003). The hypnotic effects of ethanol are
diminished in mutant mice that lack the N-type calcium channel (Newton et al. 2004), which show
both decreased ethanol preference and levels of ethanol consumption compared with wild-type
mice.
In contrast to the other voltage-gated channels, T-type channels have low voltage thresholds for
activation. These channels have been implicated in the generation of burst responses in thalamic
neurons that produce spindle waves during Stage II sleep (Kim et al. 1995). Low concentrations of
ethanol may enhance T-type currents in the thalamus, although higher concentrations of ethanol
block these currents (Mu et al. 2003). The chronic self-administration of ethanol reduces T-type
calcium currents in dorsal-lateral geniculate nucleus cells in the thalamus of monkeys (Carden et
- 2006), an effect that may play a role in the disruptive effects of ethanol on sleep (Carden et al.
2006).
Inwardly rectifying potassium channels can decrease neuronal excitability. G protein–coupled,
inwardly rectifying potassium channels (GIRKs) may be activated by intoxicating concentrations of
ethanol (Lewohl et al. 1999). Mutant mice, from which the GIRK2 type of potassium channel is
deleted, consume more ethanol than do wild-type mice (Blednov et al. 2001).
Large-conductance, BK channels are voltage-dependent potassium channels that are also activated
by increases in intracellular calcium. BK channels may be abundant in the medium spiny neurons of
the NAcc (Martin et al. 2004). BK channel subunits have been identified in several other brain
regions, including the amygdala, cerebellum, hippocampus, and neocortex (Edgerton and Reinhart
2003; Faber and Sah 2002; Hicks and Marrion 1998; Kang et al. 1996). These channels modulate
the shape and frequency of action potentials and control neurotransmitter release (Shao et al.
1999). Ethanol activates BK channels in the NAcc (Martin et al. 2004) at concentrations associated
with intoxication. Although the behavioral significance of ethanol-induced activation of BK channels
is not well understood, in the nematode Caenorhabditis elegans BK channels may be the onlyPrint: Chapter 8. Neurobiology of Alcohol http://www.psychiatryonline.com/popup.aspx?aID=345891&print=yes…
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proteins through which ethanol acts to produce intoxication (Davies et al. 2003).
CONCLUSION
Ethanol can alter the activity of cAMP second messenger pathways by stimulating some isoforms of
adenylyl cyclase. This effect can alter the phosphorylation state of receptor systems, most notably
the NMDA receptor system. This action may also influence the function of CREB and NPY systems,
which may play a critical role in regulating drinking behaviors. Another neuropeptide, CRH, through
actions involving both the HPA axis and extra-HPA systems, may also play a key role in ethanol
consumption, possibly by interacting with the glutamate system through NMDA receptor effects.
Like many other drugs of abuse, ethanol promotes the release of dopamine within the mesolimbic
system. This action may be linked to the rewarding actions of ethanol. The dopamine-releasing
effects of ethanol may be enhanced as a result of repeated exposure to this agent. Nicotinic
receptors located in the VTA may mediate some of the dopamine-releasing actions of ethanol.
Cannabinoid CB1 and serotonin 5-HT3 and 5-HT1B receptors may also facilitate
mesolimbic-dopamine release associated with ethanol use. Whereas and opioid receptors also
appear to facilitate dopamine release following ethanol intake, the opioid receptor appears to
inhibit this effect.
The anxiolytic, hypnotic, motor-impairing, and sedative actions of ethanol most likely result from
activation of GABAA receptor systems. Mechanisms that mediate the actions of ethanol on these
systems remain a subject of intense investigation. Proposed mechanisms include ethanol-induced
presynaptic release of GABA, increases in neurosteroid concentrations in the brain, and direct
interactions between ethanol and GABAA receptors that contain 4 or 6 subunits in combination
with the subunit.
Each of the major types of glutamate receptors may play a role in alcoholism. The NMDA receptor
systems are subject to the inhibitory actions of ethanol. These actions produce some of the
stimulus effects associated with ethanol use and may be tied to the rewarding actions of ethanol.
mGluRs, particularly the mGluR5 receptor, may regulate ethanol self-administration, possibly
through an interaction with NMDA receptors. Although they may not directly interact with ethanol,
AMPA receptors may regulate ethanol-seeking behavior. Kainate receptors in select brain regions
are subject to the inhibitory actions of ethanol, but the behavioral implications of this effect remain
to be determined.
Ethanol exposure alters the functioning of L-, N-, P-, and T-type voltage-dependent calcium
channels. Ethanol-induced alterations of L-type calcium channels may play a role in the
development of ethanol withdrawal symptoms. N- and T-type calcium channels may mediate some
of the sedative effects of ethanol and its impact on the quality of sleep experienced. Recent
evidence suggests that BK channels may play an important role in ethanol intoxication.
The decreased sensitivity of GABAA receptors and the increased sensitivity of NMDA receptor
systems have been implicated in the development of neuronal hyperexcitability that occurs during
the early phases of ethanol withdrawal. Withdrawal symptoms can be attenuated by the
administration of either positive modulators of GABAA receptor systems, such as the
benzodiazepines, or NMDA receptor antagonists, such as memantine. Alterations in subunit
expression that occur with prolonged ethanol exposure may play a role in ethanol withdrawal.
Ethanol withdrawal, however, may also involve more subtle changes, such as alterations in the
local trafficking of receptors through the plasma membrane and in gene expression.
As discussed in this chapter, considerable knowledge has accrued concerning the neurobiology of
ethanol drinking behavior and ethanol’s behavioral effects. This growing understanding of the
neurobiology of alcohol can be expected to continue to inform the search for medications to treat
alcohol use disorders, reflecting an iterative process of preclinical and clinical development.
KEY POINTS
The antianxiety, motor-impairing, and sedative-hypnotic effects of ethanol may be produced by thePrint: Chapter 8. Neurobiology of Alcohol http://www.psychiatryonline.com/popup.aspx?aID=345891&print=yes…
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activation of -aminobutyric (GABA)A receptors.
Ethanol may interact with GABAA receptors by enhancing GABA release, increasing brain neurosteroid
levels, and/or by directly acting on GABAA receptors that contain 4 or 6 subunits.
Decreased GABAA receptor sensitivity and N-methyl-D-aspartate (NMDA) receptor up-regulation may play
important roles in the development of physical dependence on ethanol.
Ethanol-induced dopamine release within the nucleus accumbens may produce the reinforcing effects of
alcohol.
Cannabinoid CB1, nicotinic, opioid, and serotonin 5-HT3 receptors may alter the reinforcing effects of
ethanol by facilitating dopamine release.
Endogenous opioid peptides, including the enkephalins, may promote ethanol consumption while other
peptides, such as neuropeptide Y, may have inhibitory effects on alcohol-seeking behaviors.
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Copyright © 2008 American Psychiatric Publishing, Inc. All Rights Reserved.
Course Content
Introduction to Neurobiology and Alcohol
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Basics of Neurobiology
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Introduction to Alcohol as a Psychoactive Substance
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Alcohol’s Pathway in the Brain
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Quiz: Understanding Basic Neurobiology
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Quiz: Alcohol’s Impact on Neurobiology
The Neurochemical Pathways of Alcohol
Alcohol’s Effects on Brain Structure and Function
Long-Term Neurobiological Consequences of Alcohol Use
Integrating Knowledge: Strategies for Mitigating Alcohol’s Impact
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