Partial reversal of ethanol-induced reductions in exploration by two benzodiazepine antagonists (flumazenil and ZK 93426)

Dopamine and benzodiazepine-dependent mechanisms regulate the EtOH-enhanced locomotor stimulation in the GABAA alpha1 subunit null mutant mice

The present study investigated the role of the alpha1-containing GABA(A) receptors in the neurobehavioral actions of alcohol. In Experiment 1, mice lacking the alpha1 subunit (alpha1 (-/-)) were tested for their capacity to initiate operant-lever press responding for alcohol or sucrose. Alcohol intake in the home cage was also measured. In Experiment 2, the alpha1 (-/-) mice were injected with a range of alcohol doses (0.875-4.0 g/kg; i.p.) to evaluate the significance of the alpha1 subunit in alcohol's stimulant actions. In Experiment 3, we determined if the alcohol-induced stimulant effects were regulated via dopaminergic (DA) or benzodiazepine (BDZ)-dependent mechanisms. To accomplish this, we investigated the capacity of DA (eticlopride, SCH 23390) and BDZ (flumazenil, betaCCt) receptor antagonists to attenuate the alcohol-induced stimulant actions. Compared with wild-type mice (alpha1 (+/+)), the null mutants showed marked reductions in both EtOH and sucrose-maintained responding, and home-cage alcohol drinking. The null mutants also showed significant increases in locomotor behaviors after injections of low-moderate alcohol doses (1.75-3.0 g/kg). betaCCt, flumazenil, eticlopride, and SCH 23390 were able to attenuate the alcohol-induced stimulation in mutant mice, in the absence of intrinsic effects. These data suggest the alpha1 receptor plays an important role in alcohol-motivated behaviors; however, it also appears crucial in regulating the reinforcing properties associated with normal ingestive behaviors. Deleting the alpha1 subunit of the GABA(A) receptor appears to unmask alcohol's stimulatory effects; these effects appear to be regulated via an interaction of both DA- and GABA(A) BDZ-dependent mechanisms.

The sleep-inducing effect of ethanol microinjection into the medial preoptic area is blocked by flumazenil

Previous studies have shown that a wide range of sedative/hypnotic agents, including ethanol, induce sleep when microinjected into the medial preoptic area (MPA) of the anterior hypothalamus. The mechanism by which ethanol acts at this site to induce sleep has not been clear, though possibilities include alterations of chloride channel function in the GABA(A)-benzodiazepine receptor complex, or increases in neuronal membrane fluidity. In order to explore the former possibility, we have microinjected into the MPA ethanol 0.24 and 0.47 microM, alone and in combination with the benzodiazepine receptor antagonist flumazenil, which has no effects on membrane fluidity or voltage-dependent calcium channel function. Ethanol microinjections significantly reduced sleep latency, and tended (P<0.06) to increase total sleep time. Flumazenil given by itself had no significant effects on sleep, but when given in combination with both doses of ethanol, blocked its hypnotic effects. These data suggest that the sleep-inducing action of ethanol microinjections into the MPA is mediated by ethanol-induced alteration of GABA(A)-benzodiazepine receptor function.

Benzodiazepine receptor antagonists modulate the actions of ethanol in alcohol-preferring and -nonpreferring rats

The pyrazoloquinoline CGS 8216 (2-phenylpyrazolo-[4,3-c]-quinolin-3 (5H)-one, 0.05-2 mg/kg) and the beta-carboline ZK 93426 (ethyl-5-isopropyl-4-methyl-beta-carboline-3-carboxylate, 1-10 mg/kg) benzodiazepine receptor antagonists were evaluated for their capacity to modulate the behavioral actions of ethanol in alcohol preferring and -nonpreferring rats. When alcohol-preferring rats were presented with a two-bottle choice test between ethanol (10% v/v) and a saccharin (0.0125% g/v) solution, both antagonists dose-dependently reduced intake of ethanol by 35-92% of control levels on day 1 at the initial 15 min interval of the 4 h limited access. Saccharin drinking was suppressed only with the highest doses. CGS 8216 (0.25 mg/kg) and ZK 93426 (4 mg/kg) unmasked the anxiolytic effects of a hypnotic ethanol dose (1.5 g/kg ethanol) on the plus maze test in alcohol-preferring rats, but potentiated the ethanol-induced suppression in alcohol-nonpreferring rats. CGS 8216 (0.25 mg/kg) and ZK 93426 (4 mg/kg) attenuated the ethanol (0.5 and 1.5 g/kg)-induced suppression in the open field in alcohol-nonpreferring rats; however, CGS 8216 potentiated the depressant effects of the lower ethanol dose (0.5 g/kg) in alcohol-preferring rats. These findings provide evidence that benzodiazepine receptor antagonists may differentially modulate the behavioral actions of ethanol in alcohol-preferring and-nonpreferring rats. It is possible that the qualitative pharmacodynamic differences seen in the present study may be related to selective breeding for alcohol preference. The findings indicate the potential for development of receptor specific ligands devoid of toxic effects which may be useful in the treatment of alcohol abuse and alcoholism.

Interactions of Ro15-4513, Ro15-1788 (flumazenil) and ethanol on measures of exploration and locomotion in rats

The present study investigated the role of the GABAA-benzodiazepine (BDZ) receptor complex in mediating ethanol (ETOH)-induced increases in exploration (head-dipping) and locomotion of rats in a holeboard test. Male Sprague-Dawley rats were selected based on low basal exploratory rates to increase the likelihood that ETOH would increase these behaviors. The effects of the BDZ partial inverse agonist, Ro15-4513 (2.5 mg/kg), and the BDZ receptor antagonist, Ro15-1788 (flumazenil) (8.0 mg/kg), alone, and in combination with ETOH (0.25, 0.50 and 0.75 g/kg, IP) were investigated. The 0.25 and 0.50 g/kg doses of ETOH markedly increased both exploration and locomotion in low exploratory rats. The ETOH-induced increases were prevented by Ro15-4513 on both measures at a dose that produced no observable intrinsic action; however, this apparent lack of intrinsic activity on exploration may have been related to the low basal rates of responding in the subjects. The BDZ antagonist, flumazenil, completely reversed the antagonistic action produced by Ro15-4513 of the ETOH-induced stimulant effects on locomotion, however, flumazenil exerted only a marginal statistically significant effect on Ro15-4513's actions on head-dipping. When flumazenil was given alone, it increased head-dipping, but was without effect on locomotion. Flumazenil did not affect ETOH-induced increases in locomotion; however, ETOH and flumazenil appeared to show agonistic effects on exploration. The different effects exerted by flumazenil alone, and in combination with ETOH on head-dipping and locomotion suggest that the actions of flumazenil on these behaviors are mediated through separate mechanisms. The research further suggests that both the anxiolytic and locomotor activational effects of ETOH are mediated through the GABAA-BDZ receptor complex.

Neurobiological mechanisms controlling aggression: preclinical developments for pharmacotherapeutic interventions

Current pharmacotherapeutic approaches to the management of violent and aggressive behavior rely mostly on agents that act as receptor agonists or antagonists at subtypes of brain dopaminergic, GABAergic, and serotonergic receptors. Ethological experimental studies in animals have shown that drugs may modulate aggression by inhibiting motor activity, by distorting aggression-provoking or -inhibiting signals, by fragmenting behavioral sequences or temporal patterning, or by increasing the rate and intensity of aggressive acts. Evidence from animal studies points to large changes in selected brain dopamine, serotonin, and GABA systems during and following aggressive and defensive behavior. However, the specificity of drugs that are currently used to control aggressive behavior through their action as agonists or antagonists at subtypes of dopamine, serotonin or GABA receptors continues to be of concern. Similar to the effects of widely used traditional neuroleptics that nonselectively antagonize dopamine receptors, the range of behaviors which is suppressed by either D1 or D2 receptor antagonists is pervasive. At present, systemic administration of dopamine receptor antagonists in animal preparations does not target aggression-specific mechanisms. The GABAA/Benzodiazepine/Chloride ionophore receptor complex is implicated in the aggression-heightening effects of alcohol and benzodiazepines. Although early reports focused on the "taming" effects of benzodiazepine anxiolytics, low doses may enhance aggression in both animals and humans. Benzodiazepine antagonists block heightened aggression after low doses of alcohol or benzodiazepines. Agonists at certain 5-HT1 receptor subtypes such as eltoprazine are potently effective in reducing aggressive behavior of males and females of various animal species under conditions that promote charging offensive-type aggression, without adversely affecting nonaggressive components of the behavioral repertoire. However, recent reports indicate that eltoprazine and related compounds may potentiate anxiety reactions in rodents, and question the behavioral specificity of these substances. Opioid receptor antagonists modulate primarily physiological and behavioral responses of defense and submission. Defeated animals show tolerance to opiate analgesia and withdrawal responses upon challenge with opioid receptor antagonists. Defensive and submissive vocalizations are potently blocked by opioid peptides. Substances that target specific receptor subtypes at serotonergic, GABAergic and opioidergic synapses are most promising for the selective modification of aggressive, defensive and submissive behavior patterns.

Prevention of the pro-aggressive effects of alcohol in rats and squirrel monkeys by benzodiazepine receptor antagonists

Pharmacological manipulations at the benzodiazepine-GABAA-chloride ionophore receptor complex modify some of the behavioral and physiological actions of alcohol (ethanol). The interactions between alcohol, benzodiazepines and aggression were examined in similar ethopharmacological studies in squirrel monkeys and in rats in confrontations with conspecifics. Dominant male squirrel monkeys were tested (1) within their social groups, and (2) in dyadic confrontations with "rival" males from a different social group, and resident male rats were tested in their home cage in confrontations with an inexperienced male intruder. Low doses of alcohol (0.1-0.3 g/kg) increased aggressive behaviors in dominant squirrel monkeys and a subgroup of resident rats, whereas high doses of alcohol (1-3 g/kg) decreased aggression and produced marked motor incoordination. Individuals that showed alcohol-enhanced aggression were selected, and pretreated with benzodiazepine antagonists (flumazenil, ZK 93426) prior to alcohol administration. Both ZK 93426 (3 mg/kg) and flumazenil (10 mg/kg) blocked the aggression-enhancing effects of alcohol in dominant squirrel monkeys and resident rats in confrontations with conspecifics. Neither compound altered the reductions in aggression and increases in inactivity produced by high doses of alcohol. Interestingly, agonist-like increased feeding and inverse agonist-like reductions in social behaviors were observed simultaneously at the same dose of flumazenil, in the same individual and testing situation. ZK 93426 did not alter feeding but also reduced social behaviors. The two antagonists were also not equipotent in their interactions with alcohol. ZK 93426 reduced alcohol-induced motor incoordination in squirrel monkeys, whereas flumazenil did not. In fact, flumazenil potentiated the effects of low doses of alcohol.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of benzodiazepine receptor inverse agonists on locomotor activity and exploration in mice

This study investigates the effects of benzodiazepine receptor inverse agonists on the locomotor and exploratory behaviour of mice when tested in a familiar environment. The weak partial inverse agonist Ro 15-3505 (0.3, 1, 3 mg/kg i.p.) significantly increased locomotion and hole-dipping in habituated mice. However, the more efficacious partial inverse agonists Ro 15-4513 (0.3, 1, 3 mg/kg i.p.) and Ro 19-4603 (0.03, 0.1, 0.3 mg/kg i.p.) had no effect on these parameters. The benzodiazepine receptor antagonist flumazenil (3, 10, 20 mg/kg i.p.) also increased locomotion and hole-dipping in habituated mice, although like Ro 15-3505, these effects were of short duration occurring largely in the first 15 min following injection. Opposite effects were obtained with the partial benzodiazepine agonist Ro 17-1812 (1, 3, 10 mg/kg i.p.) which produced a longer-lasting significant decrease in hole-dipping behaviour in habituated mice without altering locomotion. Finally, in contrast to its effects in habituated animals, Ro 15-3505 (0.3, 1, 3 mg/kg i.p.) did not modify either locomotion or exploration in mice which were tested in a novel environment, showing that the effects of the inverse agonist were state-dependent. This demonstration that, under certain conditions, the weak benzodiazepine receptor inverse agonist Ro 15-3505 and the antagonist flumazenil, produce behavioural activation is in accordance with the work of others suggesting that these classes of compound may increase arousal and may therefore be of some value in treatment of memory disorders.

Anxiolytic effects of nitrous oxide in mice in the light-dark and holeboard exploratory tests

To investigate anxiolytic effects of nitrous oxide (N2O), male mice were tested in two exploratory models--a two-chambered light-dark (L-D) unit and a holeboard. Tests were conducted inside a glovebag through which one of three mixtures of N2O and oxygen (25, 50 and 75% N2O) or room air (RA) was circulated at a flow rate of 10 l/min. The principal findings in the L-D unit were a concentration-related increase in number of interdepartmental transitions and a generalized increase in time spent on the light side. Nitrous oxide effectively elevated transitions in the L-D unit at a lower concentration (25% N2O) than was required to increase locomotor activity in an open field (50% N2O), suggesting that these two measures are at least partially independent; transitions might reflect a specific exploratory component of locomotor behavior. In the holeboard test, a concentration-related increase in number of head dips was observed. Pretreatment with naltrexone-HCl or saline vehicle revealed a contribution by an endogenous opioid-linked locomotor stimulant effect in some measures. A dose-related reversal by flumazenil of 50% N2O-induced shifts in number of head dips and time spent head-dipping implicates a benzodiazepine receptor. Both paradigms, in particular the holeboard, should prove useful in future N2O research.

Alcohol, the chloride ionophore and endogenous ligands for benzodiazepine receptors

Considerable evidence suggests that at least some of the effects of ethanol are mediated by an action on the GABAA receptor chloride channel complex. More speculative is the suggestion that ethanol might interact with endogenous ligands for the benzodiazepine receptor on the complex. This paper considers the evidence for such interactions.

Activating the damaged basal forebrain cholinergic system: tonic stimulation versus signal amplification

The hypothesis that the cognitive decline in senile dementia is related to the loss of cortical cholinergic afferent projections predicts that pharmacological manipulations of the remaining cholinergic neurons will have therapeutic effects. However, treatment with cholinesterase inhibitors or muscarinic agonists has been, for the most part, largely unproductive. These drugs seem to disrupt the normal patterning of cholinergic transmission and thus may block proper signal processing. An alternative pharmacological strategy which focuses on the amplification of presynaptic activity without disrupting the normal patterning of cholinergic transmission appears to be more promising. Such a strategy may make use of the normal GABAergic innervation of basal forebrain cholinergic neurons in general, and in particular of the inhibitory hyperinnervation of remaining cholinergic neurons which may develop under pathological conditions. Disinhibition of the GABAergic control of cholinergic activity is assumed to intensify presynaptic cortical cholinergic activity and to enhance cognitive processing. Although the extent to which compounds such as the benzodiazepine receptor antagonist beta-carboline ZK 93,426 act via the basal forebrain GABA-cholinergic link is not yet clear, the available data suggest that the beneficial behavioral effects of this compound established in animals and humans are based on indirect cholinomimetic mechanisms. It is proposed that an activation of residual basal forebrain cholinergic neurons can be achieved most physiologically via inhibitory modulation of afferent GABAergic transmission. This modulation may have a therapeutic value in treating behavioral syndromes associated with cortical cholinergic denervation.

Interactions of ethanol with benzodiazepine receptor ligands in tests of exploration, locomotion and anxiety

The ability of benzodiazepine receptor ligands to modify the behavioral effects of ethanol in tests of exploration, locomotion and anxiety are reviewed. Drugs with inverse agonist activity appear capable of consistently antagonizing the reductions in exploration and anxiety caused by ethanol. In contrast, the locomotor stimulant action of ethanol has appeared relatively insensitive to inverse agonists, suggesting that this effect may not be mediated primarily by an action of ethanol at the benzodiazepine/GABA receptor complex.