Increased regional gray matter atrophy and enhanced functional connectivity in male multiple sclerosis patients

Evidence suggests that sex/gender is an important factor for understanding multiple sclerosis (MS) and that some of its neuropathological consequences might manifest earlier in males. In the present study, we assessed gray matter (GM) volume and functional connectivity (FC) in a sample of female and male MS patients (MSp) and female and male healthy controls (HCs). As compared to female MSp, male MSp showed decreased GM volume in the bilateral frontal areas and increased FC between different brain regions. Because both sets of changes correlated significantly and no differences in cognitive performance were observed, we suggest that the FC increase observed in male MSp acts as a compensatory mechanism for their more extensive GM loss and that it promotes a functional convergence between male- and female-MSp.

Modulation of chromatin modification facilitates extinction of cocaine-induced conditioned place preference

BACKGROUND

Recent evidence suggests that epigenetic mechanisms have an important role in the development of addictive behavior. However, little is known about the role of epigenetic mechanisms in the extinction of drug-induced behavioral changes. In this study, we examined the ability of histone deacetylase (HDAC) inhibitors to facilitate extinction and attenuate reinstatement of cocaine-induced conditioned place preference (CPP).

METHODS

C57BL/6 mice were subject to cocaine-induced CPP using 20 mg/kg dose. To facilitate extinction, mice were administered an HDAC inhibitor following nonreinforced exposure to the conditioned context. To measure persistence, mice were subject to a reinstatement test using 10 mg/kg dose of cocaine.

RESULTS

We demonstrate that HDAC inhibition during extinction consolidation can facilitate extinction of cocaine-induced CPP. Animals treated with an HDAC inhibitor extinguished cocaine-induced CPP both more quickly and to a greater extent than did vehicle-treated animals. We also show that the extinction of cocaine seeking via HDAC inhibition modulates extinction learning such that reinstatement behavior is significantly attenuated. Acetylation of histone H3 in the nucleus accumbens following extinction was increased by HDAC inhibition.

CONCLUSIONS

This study provides the first evidence that modulation of chromatin modification can facilitate extinction and prevent reinstatement of drug-induced behavioral changes. These findings provide a potential novel approach to the development of treatments that facilitate extinction of drug-seeking behavior.

Selective boosting of transcriptional and behavioral responses to drugs of abuse by histone deacetylase inhibition

Histone acetylation and other modifications of the chromatin are important regulators of gene expression and, consequently, may contribute to drug-induced behaviors and neuroplasticity. Earlier studies have shown that a reduction in histone deacetylase (HDAC) activity results in the enhancement of some psychostimulant-induced behaviors. In this study, we extend those seminal findings by showing that the administration of the HDAC inhibitor sodium butyrate enhances morphine-induced locomotor sensitization and conditioned place preference. In contrast, this compound has no effects on the development of morphine tolerance and dependence. Similar effects were observed for cocaine and ethanol-induced behaviors. These behavioral changes were accompanied by a selective boosting of a component of the transcriptional program activated by chronic morphine administration that included circadian clock genes and other genes relevant to addictive behavior. Our results support a specific function for histone acetylation and the epigenetic modulation of transcription at a reduced number of biologically relevant loci on non-homeostatic, long-lasting, drug-induced behavioral plasticity.

Inhibition of cAMP responsive element binding protein in striatal neurons enhances approach and avoidance responses toward morphine--and morphine withdrawal-related cues

To investigate the role of cAMP responsive element binding protein (CREB)-dependent gene expression in morphine induced behaviors, we examined bitransgenic mice expressing a dominant and strong inhibitor of the CREB family of transcription factors, A-CREB, in striatal neurons in a regulatable manner. The expression of A-CREB in the striatum enhanced both morphine-induced conditioned place preference and morphine withdrawal-induced conditioned place avoidance. Our experiments thereby support a role for CREB in striatal neurons regulating approach and avoidance responses toward drug-related cues.

Epigenetic mechanisms underlying extinction of memory and drug-seeking behavior

An increasing body of evidence shows that structural modifications of chromatin, the DNA-protein complex that packages genomic DNA, do not only participate in maintaining cellular memory (e.g., cell fate), but they may also underlie the strengthening and maintenance of synaptic connections required for long-term changes in behavior. Accordingly, epigenetics has become a central topic in several neurobiology fields such as memory, drug addiction, and several psychiatric and mental disorders. This interest is justified as dynamic chromatin modifications may provide not only transient but also stable (or even potentially permanent) epigenetic marks to facilitate, maintain, or block transcriptional processes, which in turn may participate in the molecular neural adaptations underlying behavioral changes. Through epigenetic mechanisms the genome may be indexed in response to environmental signals, resulting in specific neural modifications that largely determine the future behavior of an organism. In this review we discuss recent advances in our understanding of how epigenetic mechanisms contribute to the formation of long-term memory and drug-seeking behavior and potentially how to apply that knowledge to the extinction of memory and drug-seeking behavior.

Automated scoring of fear-related behavior using EthoVision software

Fear conditioning is a frequently used paradigm for assessing learning and memory in rodents. Traditionally researchers have relied upon scoring of fear-related behavior by human observation, which can be difficult and subjective and thus vary among investigators. The goal of this study was to evaluate the ability of EthoVision tracking software (Noldus Information Technology Inc.) to reliably and accurately score fear-related behavior in mice. Specifically, we were interested in its ability to accurately track mice and score immobility as a fear-related behavior during contextual and cued fear conditioning. Contextual and cued fear conditioning were performed in modified PhenoTyper chambers (Noldus Information Technology Inc.) fitted with grid floors to deliver a scrambled foot shock. Our results demonstrate that we have identified parameters in EthoVision that can accurately track mice and be used for automated scoring of immobility that is nearly identical to scoring by human observation. Together, EthoVision software and the modified PhenoTyper chambers provide an excellent system for the reliable and accurate measurement of fear-related behavior in a high-throughput manner.

Glutamate receptors on dopamine neurons control the persistence of cocaine seeking

Cocaine strengthens excitatory synapses onto midbrain dopamine neurons through the synaptic delivery of GluR1-containing AMPA receptors. This cocaine-evoked plasticity depends on NMDA receptor activation, but its behavioral significance in the context of addiction remains elusive. Here, we generated mice lacking the GluR1, GluR2, or NR1 receptor subunits selectively in dopamine neurons. We report that in midbrain slices of cocaine-treated mice, synaptic transmission was no longer strengthened when GluR1 or NR1 was abolished, while in the respective mice the drug still induced normal conditioned place preference and locomotor sensitization. In contrast, extinction of drug-seeking behavior was absent in mice lacking GluR1, while in the NR1 mutant mice reinstatement was abolished. In conclusion, cocaine-evoked synaptic plasticity does not mediate concurrent short-term behavioral effects of the drug but may initiate adaptive changes eventually leading to the persistence of drug-seeking behavior.

Deletion of Go2alpha abolishes cocaine-induced behavioral sensitization by disturbing the striatal dopamine system

The alpha-subunits of the trimeric Go class of GTPases, comprising the splice variants Go1alpha and Go2alpha, are abundantly expressed in brain and reside on both plasma membrane and synaptic vesicles. Go2alpha is involved in the vesicular storage of monoamines but its physiological relevance is still obscure. We now show that genetic depletion of Go2alpha reduces motor activity induced by dopamine-enhancing drugs like cocaine, as repeated injections of cocaine fail to provoke behavioral sensitization in Go2alpha(-/-) mice. In Go2alpha(-/-) mice, D1 receptor signaling in the striatum is attenuated due to a reduced expression of Golf alpha and Gs alpha. Following cocaine treatment, Go2alpha(-/-) mice have lower D1 and higher D2 receptor amounts compared to wild-type mice. The lack of behavioral sensitization correlates with reduced dopamine levels in the striatum and decreased expression of tyrosine hydroxylase. One reason for the neurochemical changes may be a reduced uptake of monoamines by synaptic vesicles from Go2alpha(-/-) mice as a consequence of a lowered set point for filling. We conclude that Go2alpha optimizes vesicular filling which is instrumental for normal dopamine functioning and for the development of drug-induced behavioral sensitization.

Etomidate and propofol-hyposensitive GABAA receptor beta3(N265M) mice show little changes in acute alcohol sensitivity but enhanced tolerance and withdrawal

Gamma-aminobutyric acid-A (GABAA) receptors are ligand-gated ion channels comprised of subunits from several classes (alpha, beta, gamma, delta). Recent studies have clearly demonstrated that the functional properties of GABAA receptors are altered following chronic ethanol administration that could provide the molecular basis for the previously proposed role of these receptors in ethanol tolerance and dependence. Because the subunit composition of GABAA receptors determines receptor pharmacology, the present study was devoted to assess if the behavioral sensitivity after acute and chronic ethanol exposure depends on beta3-containing GABAA receptors. In the present study, we used knock-in mice harboring a point mutation (N265M) in the second transmembrane region of the beta3 subunit of the GABAA receptor in order to study acute and chronic behavioral effects of ethanol. More specifically, we tested tolerance to loss of righting reflex (LORR) and the development of withdrawal signs after chronic ethanol exposure using ethanol vapor chambers. Our results show that the beta3(N265M) mutation does not play a major modulatory role of acute ethanol-induced LORR. However, following repeated LORR testing, enhanced tolerance to the intoxicating effects of ethanol was observed--a finding which was unrelated to the pharmacokinetics of ethanol as both genotypes had the same blood alcohol concentrations following repeated LORR testing. In addition, following chronic alcohol vapor exposure, mouse mutants displayed increased handling-induced convulsions during withdrawal. The results of the present study suggest that the alcohol effects abolished by the beta3(N265M) mutation do not play a dominant role in acute alcohol intoxication but influence ethanol tolerance and withdrawal.

Ethanol self-administration and reinstatement of ethanol-seeking behavior in Per1(Brdm1) mutant mice

RATIONALE

Alcohol consumption shows circadian rhythmicity, i.e., alcohol preference and intake change with circadian time. Circadian rhythmicity is controlled by a biological clock, which has been shown to govern behavioral, physiological, and hormonal processes in synchronization with internal as well as external cues. Molecular components of the clock include circadian clock genes such as period (Per) 1, 2, and 3. Previously, our lab demonstrated the involvement of mouse Per1 (mPer1) and Per2 (mPer2) in modulating cocaine sensitization and reward. What is more, we investigated voluntary alcohol consumption in Per2 ( Brdm1 ) mice with the results suggesting a relationship between this circadian clock gene and ethanol consumption. Objective To further complement the mPer2 study, our lab proceeded to assess mPer1's possible role on alcohol intake using operant and free choice two bottle paradigms.

METHODS

Using operant conditions, Per1 ( Brdm1 ) and wild type mice were trained to self-administer ethanol (10%) under a fixed ratio 1 (FR1) paradigm. This was ensued by a progressive ratio (PR) schedule. Furthermore, extinction sessions were introduced, followed by reinstatement measures of ethanol-seeking behavior. In another set of animals, the mice were exposed to voluntary long-term alcohol consumption, ensued by a 2-month deprivation phase, after which the alcohol deprivation effect (ADE) was measured.

RESULTS

Mutant mice did not display a significantly divergent number of reinforced lever presses (FR1 and PR) than wild type animals. Furthermore, no significant differences between groups were obtained regarding reinstatement of ethanol-seeking behavior. Similar results were obtained in the two bottle free choice paradigm. Specifically, no genotype differences concerning consumption and preference were observed over a broad range of different ethanol concentrations. Moreover, after the deprivation phase, both groups exhibited significant ADEs, yet no genotype differences.

CONCLUSIONS

Contrary to the mPer2 data, the present findings do not suggest a relationship between the circadian clock gene mPer1 and ethanol reinforcement, seeking, and relapse behavior.

IL-6 knockout mice exhibit resistance to stress-induced development of depression-like behaviors

Cytokine-dependent mechanisms in the CNS have been implicated in the pathogenesis of depression. Interleukin-6 is upregulated in depressed patients and dowregulated by antidepressants. It is, however, unknown whether IL-6 is involved in the pathogenesis of depression. We subjected IL-6-deficient mice (IL-6(-/-)) to depression-related tests (learned helplessness, forced swimming, tail suspension, sucrose preference). We also investigated IL-6 in the hippocampus of stressed wild-type mice. IL-6(-/-) mice showed reduced despair in the forced swim, and tail suspension test, and enhanced hedonic behavior. Moreover, IL-6(-/-) mice exhibited resistance to helplessness. This resistance may be caused by the lack of IL-6, because stress increased IL-6 expression in wild-type hippocampi. This suggests that IL-6 is a component in molecular mechanisms in the pathogenesis of depression. IL-6(-/-) mice represent tools to study IL-6-dependent signaling pathways in the pathophysiology of depression in vivo. Moreover, these mice may support the screening of compounds for depression by altering cytokine-mediated signaling.

Involvement of the AMPA receptor GluR-C subunit in alcohol-seeking behavior and relapse

Craving and relapse are core symptoms of drug addiction and alcoholism. It is suggested that, after chronic drug consumption, long-lasting neuroplastic changes within the glutamatergic system are important determinants of addictive behavior. Here, we show that the AMPA type glutamate receptor plays a crucial role in alcohol craving and relapse. We observed, in two animal models of alcohol craving and relapse, that the AMPA antagonist GYKI 52466 [1-(4-aminophenyl)-4-methyl-7, 8-methylenedioxy-5H-2, 3-benzodiazepine] dose-dependently reduced cue-induced reinstatement of alcohol-seeking behavior and the alcohol deprivation effect. The involvement of the AMPA receptor in these phenomena was further studied using mice deficient for the GluR-C AMPA subunit [GluR-C knock-out (KO)]. GluR-C KOs displayed a blunted, cue-induced reinstatement response and alcohol deprivation effect, when compared with wild-type controls; however, no differences between genotypes could be observed regarding ethanol self-administration under operant or home cage drinking conditions. These results imply a role for GluR-C in alcohol relapse, although this phenotype could also be attributable to a reduction in the total number of AMPA receptors in specific brain areas. In conclusion, AMPA receptors seem to be involved in the neuroplastic changes underlying alcohol seeking behavior and relapse. Thus, AMPA receptors represent a novel therapeutic target in preventing relapse.

Behavioural assessment of drug reinforcement and addictive features in rodents: an overview

Some psychoactive drugs are abused because of their ability to act as reinforcers. As a consequence behavioural patterns (such as drug-seeking/drug-taking behaviours) are promoted that ensure further drug consumption. After prolonged drug self-administration, some individuals lose control over their behaviour so that these drug-seeking/taking behaviours become compulsive, pervading almost all life activities and precipitating the loss of social compatibility. Thus, the syndrome of addictive behaviour is qualitatively different from controlled drug consumption. Drug-induced reinforcement can be assessed directly in laboratory animals by either operant or non-operant self-administration methods, by classical conditioning-based paradigms such as conditioned place preference or sign tracking, by facilitation of intracranial electric self-stimulation, or, alternatively by drug-induced memory enhancement. In contrast, addiction cannot be modelled in animals, at least as a whole, within the constraints of the laboratory. However, various procedures have been proposed as possible rodent analogues of addiction's major elements including compulsive drug seeking, relapse, loss of control/impulsivity, and continued drug consumption despite negative consequences. This review provides an extensive overview and a critical evaluation of the methods currently used for studying drug-induced reinforcement as well as specific features of addictive behaviour. In addition, comic strips that illustrate behavioural methods used in the drug abuse field are provided given for free download under http://www.zi-mannheim/psychopharmacology.de.

Learned helplessness: validity and reliability of depressive-like states in mice

The learned helplessness paradigm is a depression model in which animals are exposed to unpredictable and uncontrollable stress, e.g. electroshocks, and subsequently develop coping deficits for aversive but escapable situations (J.B. Overmier, M.E. Seligman, Effects of inescapable shock upon subsequent escape and avoidance responding, J. Comp. Physiol. Psychol. 63 (1967) 28-33 ). It represents a model with good similarity to the symptoms of depression, construct, and predictive validity in rats. Despite an increased need to investigate emotional, in particular depression-like behaviors in transgenic mice, so far only a few studies have been published using the learned helplessness paradigm. One reason may be the fact that-in contrast to rats (B. Vollmayr, F.A. Henn, Learned helplessness in the rat: improvements in validity and reliability, Brain Res. Brain Res. Protoc. 8 (2001) 1-7)--there is no generally accepted learned helplessness protocol available for mice. This prompted us to develop a reliable helplessness procedure in C57BL/6N mice, to exclude possible artifacts, and to establish a protocol, which yields a consistent fraction of helpless mice following the shock exposure. Furthermore, we validated this protocol pharmacologically using the tricyclic antidepressant imipramine. Here, we present a mouse model with good face and predictive validity that can be used for transgenic, behavioral, and pharmacological studies.

Lead-induced catalase activity differentially modulates behaviors induced by short-chain alcohols

Acute lead administration produces a transient increase in brain catalase activity. This effect of lead has been used to assess the involvement of brain ethanol metabolism, and therefore centrally formed acetaldehyde, in the behavioral actions of ethanol. In mice, catalase is involved in ethanol and methanol metabolism, but not in the metabolism of other alcohols such as 1-propanol or tert-butanol. In the present study, we assessed the specificity of the effects of lead acetate on catalase-mediated metabolism of alcohols, and the ability of lead to modulate the locomotion and loss of the righting reflex (LRR) induced by 4 different short-chain alcohols. Animals were pretreated i.p. with lead acetate (100 mg/kg) or saline, and 7 days later were injected i.p. with ethanol (2.5 or 4.5 g/kg), methanol (2.5 or 6.0 g/kg), 1-propanol (0.5 or 2.5 g/kg) or tert-butanol (0.5 or 2.0 g/kg) for locomotion and LRR, respectively. Locomotion induced by ethanol was significantly potentiated in lead-treated mice, while methanol-induced locomotion was reduced by lead treatment. The loss of righting reflex induced by ethanol was shorter in lead-treated mice, and lead produced the opposite effect in methanol-treated mice. There was no effect of lead on 1-propanol or tert-butanol-induced behaviors. Lead treatment was effective in inducing catalase activity and protein both in liver and brain. These results support the hypothesis that the effects of lead treatment on ethanol-induced behaviors are related to changes in catalase activity, rather than some nonspecific effect that generalizes to all alcohols.

Social and structural housing conditions influence the development of a depressive-like phenotype in the learned helplessness paradigm in male mice

Structural and social factors are known to play a crucial role in the pathogenesis of depression. Since animal models of depression are a major tool to gain insights into the mechanisms involved in the pathophysiology of this disease it is important not only to exploit but also to be aware of factors that may affect these models. As housing represents a fundamental external factor, which is controversially debated to affect the animals' emotionality, this study aimed to investigate the impact of different social and structural housing conditions on the development of a depressive-like syndrome in the learned helplessness paradigm. Group housing in an impoverished environment led to an increased vulnerability in the learned helplessness paradigm. Groups that were housed enriched, however, were less helpless. Furthermore impoverished conditions did not increase the vulnerability in single housed animals. Regarding emotionality in the animals, basal anxiety was reduced and the exploration was enhanced by group housing and enriched environment. These results suggest that housing conditions significantly influence the outcome of learned helplessness studies.

Reduced sensitivity to sucrose in rats bred for helplessness: a study using the matching law

Anhedonia is a core symptom of depression. As it cannot be directly assessed in rodents, anhedonia is usually inferred from a reduced consumption of, or preference for, a reinforcer. In the present study we tried to improve the measurement of anhedonia by performing a detailed preference analysis based on the generalized matching law and tested its sensitivity in rats congenitally prone (cLH) or resistant (cNLH) to learned helplessness. According to the current interpretation of learned helplessness as a model for depression, a reduction in the rewarding properties of sucrose in cLH rats was hypothesized. Our results revealed that the 'preference allocation' index provided by this test, but not the traditional measures of sucrose consumption or preference over water, was significantly lower in cLH rats, and was correlated with the helpless behaviour as measured in an escape procedure. Therefore, it is clear that more subtle preference measures provided by the analysis of choice using the matching law principles are more sensitive and discriminative than those based on consumption of, or preference for, a single concentration of sucrose over water. Moreover, our data are in agreement with the proposed relationship between helplessness and sucrose preference, and support the usefulness of the cLH and cNLH rats as a model of depression.

Effect of selective antagonism of mu(1)-, mu(1/2)-, mu(3)-, and delta-opioid receptors on the locomotor-stimulating actions of ethanol

Previous studies have demonstrated that administration of nonspecific opioid antagonists such as naltrexone or naloxone reduces ethanol-induced locomotor activity in mice. However, because of their broad pharmacological profile, it remains unclear through which opioid receptor this antagonism is achieved. Therefore, the present study was aimed at further investigating the role of the different opioid receptors in ethanol-induced (2.5 g/kg) locomotion in mice. First, we compared the effect of naltrexone (0-2 mg/kg) on ethanol-induced locomotion with that of the selective delta-opioid receptor antagonist, naltrindole (0-10 mg/kg). Results of this first set of data revealed that naltrexone completely blocked this effect of ethanol at doses suggested to occupy only mu-opioid receptors, and naltrindole did not modify ethanol-induced locomotion. In a second set of experiments, we further investigated the involvement of mu-opioid receptors in ethanol-stimulated motor activity by assessing the implication of mu(1)-, mu(1/2)-, and mu(3)-opioid receptor subtypes. Results revealed that mu(1/2)-, and to a lesser extent mu(3)-, but not mu(1)-opioid receptor subtypes are involved in the psychomotor actions of ethanol. Data are discussed together with previous results which have emphasized the critical dependence of ethanol-induced motor behaviors on opioid receptors, as well as, of the integrity of beta-endorphin synthesizing neurons from the hypothalamic Arcuate Nucleus.

Brain catalase activity inhibition as well as opioid receptor antagonism increases ethanol-induced HPA axis activation

BACKGROUND

Growing evidence indicates that brain catalase activity is involved in the psychopharmacological actions of ethanol. Recent data suggest that participation of this enzymatic system in some ethanol effects could be mediated by the endogenous opioid system. The present study assessed whether brain catalase has a role in ethanol-induced activation of the HPA axis, a neuroendocrine system modulated by the endogenous opioid neurotransmission.

METHODS

Swiss male mice received an intraperitoneal injection of the catalase inhibitor 3-amino-1,2,4-triazole (AT; 0-1 g/kg), and 0 to 20 hr after this administration, animals received an ethanol (0-4 g/kg; intraperitoneally) challenge. Thirty, 60, or 120 min after ethanol administration, plasma corticosterone levels were determined immunoenzymatically. In addition, we tested the effects of 45 mg/kg of cyanamide (another catalase inhibitor) and 0 to 2 mg/kg of naltrexone (nonselective opioid receptor antagonist) on ethanol-induced enhancement in plasma corticosterone values.

RESULTS

The present study revealed that AT boosts ethanol-induced increase in plasma corticosterone levels in a dose- and time-dependent manner. However, it did not affect corticosterone values when measured after administration of saline, cocaine (4 mg/kg, intraperitoneally), or morphine (30 mg/kg, intraperitoneally). The catalase inhibitor cyanamide (45 mg/kg, intraperitoneally) also increased ethanol-related plasma corticosterone levels. These effects of AT and cyanamide on ethanol-induced corticosterone values were observed under treatment conditions that decreased significantly brain catalase activity. Indeed, a significant correlation between effects of catalase manipulations on both variables was found. Finally, we found that the administration of naltrexone enhanced the levels of plasma corticosterone after the administration of saline or ethanol.

CONCLUSIONS

This study shows that the inhibition of brain catalase increases ethanol-induced plasma corticosterone levels. Results are discussed together with previous findings suggesting a putative linkage between brain ethanol metabolism and the endogenous opioid system to explain some of the neuroendocrine effects of ethanol.

The clock gene Per2 influences the glutamatergic system and modulates alcohol consumption

Period (Per) genes are involved in regulation of the circadian clock and are thought to modulate several brain functions. We demonstrate that Per2(Brdm1) mutant mice, which have a deletion in the PAS domain of the Per2 protein, show alterations in the glutamatergic system. Lowered expression of the glutamate transporter Eaat1 is observed in these animals, leading to reduced uptake of glutamate by astrocytes. As a consequence, glutamate levels increase in the extracellular space of Per2(Brdm1) mutant mouse brains. This is accompanied by increased alcohol intake in these animals. In humans, variations of the PER2 gene are associated with regulation of alcohol consumption. Acamprosate, a drug used to prevent craving and relapse in alcoholic patients is thought to act by dampening a hyper-glutamatergic state. This drug reduced augmented glutamate levels and normalized increased alcohol consumption in Per2(Brdm1) mutant mice. Collectively, these data establish glutamate as a link between dysfunction of the circadian clock gene Per2 and enhanced alcohol intake.

Catalase inhibition in the Arcuate nucleus blocks ethanol effects on the locomotor activity of rats

Previous studies have demonstrated that there is a bidirectional modulation of ethanol-induced locomotion produced by drugs that regulate brain catalase activity. In the present study we have assessed the effect in rats of intraperitoneal, intraventricular or intracraneal administration of the catalase inhibitor sodium azide in the locomotor changes observed after ethanol (1 g/kg) administration. Our results show that sodium azide prevents the effects of ethanol in rats locomotion not only when sodium azide was systemically administered but also when it was intraventricularly injected, then confirming that the interaction between catalase and ethanol takes place in Central Nervous System (CNS). Even more interestingly, the same results were observed when sodium azide administration was restricted to the hypothalamic Arcuate nucleus (ARC), a brain region which has one of the highest levels of expression of catalase. Therefore, the results of the present study not only confirm a role for brain catalase in the mediation of ethanol-induced locomotor changes in rodents but also point to the ARC as a major neuroanatomical location for this interaction. These results are in agreement with our reports showing that ethanol-induced locomotor changes are clearly dependent of the ARC integrity and, especially of the POMc-synthesising neurons of this nucleus. According to these data we propose a model in which ethanol oxidation via catalase could produce acetaldehyde into the ARC and to promote a release of beta-endorphins that would activate opioid receptors to produce locomotion and other ethanol-induced neurobehavioural changes.

Reduced sensitivity to reward in CB1 knockout mice

RATIONALE

Previous studies have demonstrated that the activation and blockade of the cannabinoid type 1 receptor (CB1) leads to an enhancement and decrease of the consumption of food and other orally ingested reinforcers, respectively.

OBJECTIVE

To gain further knowledge about the role of CB1 in sucrose/saccharin reinforcing efficacy and intake, we tested CB1 knockout (CB1-KO) and littermate wild-type (WT) control mice in several self-administration experimental protocols.

METHODS

Operant (fixed or progressive ratio schedule) and non-operant conditioning procedures were used. In addition, a choice analysis based on the "matching law" as well as a microstructural analysis of the intra-session pattern of self-administration was performed.

RESULTS

CB1-KO mice consume less sucrose under operant conditions or when using a two-bottle free choice procedure. Moreover, as revealed by additional behavioural analysis, CB1-KO mice exhibit a decreased sensitivity to the rewarding properties of sucrose. In agreement with this finding, the differences between WT and CB1-KO mice faded away when the palatability of sucrose was devaluated by adding quinine, but not when a non-caloric sweetener, saccharin, was available.

CONCLUSIONS

These results demonstrate a modulatory role of CB1 in the determination of the rewarding properties of sucrose and probably, as suggested by previous studies, other reinforcers.

Ethanol intake and motor sensitization: the role of brain catalase activity in mice with different genotypes

The C57BL/6J strain of inbred mice shows a characteristic pattern of ethanol-induced behaviors: very weak acute locomotor stimulation, a lack of locomotor-sensitizing effect of ethanol, and a high level of ethanol intake. This strain has relatively low levels of activity of the ethanol metabolizing enzyme catalase, and it has been proposed that brain catalase plays a role in the modulation of some behavioral effects of ethanol. In the first study of the present paper, we investigated the effects of pharmacological manipulations of brain catalase activity on C57BL/6J mice in acute ethanol-induced locomotion and ethanol intake. Results indicated that the reduction in motor activity produced by ethanol was reversed by pretreatment with catalase potentiators and it was enhanced by catalase inhibitors. In addition, ethanol intake was highly correlated with brain catalase activity in mice treated with a catalase potentiator. In the second study, F1 hybrid mice (SWXB6) from the outbred Swiss-Webster mice and the inbred C57BL/6J mice were used. Basal brain catalase activity levels of F1 mice were intermediate between to those of the two progenitor genotypes. That profile of catalase activity was parallel to the acute-ethanol-induced locomotion and to repeated-ethanol-induced motor sensitization effects observed across the three types of mice. These data suggest that brain catalase activity modifications in the C57BL/6J strain change the pattern of several ethanol-related behaviors in this inbred mouse.

Opposite effects of acute versus chronic naltrexone administration on ethanol-induced locomotion

Several studies have pointed out that the mu opioid receptor (MOR) can play a key role in some of the behavioural effects of ethanol. In the present study, the implication of the MOR in ethanol-induced locomotion in mice was assessed. First, the effects of the administration of different naltrexone doses (0.001-1.000 mg/kg) on the locomotor changes produced by ethanol (2.5 g/kg) were evaluated. In a second set of experiments, the ability of repeated naltrexone (6 mg/kg) administrations to modify the effects of ethanol was also assessed on mice locomotion. The results of the present study revealed that an acute naltrexone administration reduced dose-dependently ethanol-induced locomotion. Conversely, after repeated naltrexone injections, a transient boost of ethanol induced locomotor activity was observed. Thus, the results of the present study revealed that the effects of these naltrexone pretreatments on ethanol-induced locomotion are similar to the previously described changes on MOR activity. Moreover, the same (acute and chronic) naltrexone pretreatments produced similar changes on the locomotion of mice after a challenge with morphine (a MOR agonist), but not after tert-butanol (an alcohol which does not release beta-endorphins) administration. Therefore, our results are discussed in terms of the proved ability of ethanol to promote the release of beta-endorphins and, consequently, to activate the MOR.

Intracerebroventricular effects of angiotensin II on a step-through passive avoidance task in rats

A wealth of evidence indicates that angiotensin II (Ang II) is involved in learning and memory. However, the precise role of this peptide in these cognitive processes is still controversial, with data indicating either an inhibitory or an enhancing action. The present study was designed to further investigate the effects of intracerebroventricular injections of Ang II (0.5, 1 or 3nmol/5microl) on a step-through passive avoidance task in male adult Wistar rats. When administered pretraining, Ang II did not affect the acquisition of passive avoidance, but markedly improved avoidance performance when given before the retrieval test. The latter effect was observed in retest sessions performed up to 72h after training. Administration of the peptide five minutes after training impaired retention of inhibitory avoidance. Therefore, Ang II may exert opposite effects on passive avoidance memory according to its interference with brain mechanisms leading to the storage or retrieval of this aversively motivated task.

[The possible role of acetaldehyde in the brain damage caused by the chronic consumption of alcohol]

AIMS

The purpose of this study is to collect and evaluate the experimental evidence suggesting that acetaldehyde, the first oxidative metabolite of ethyl alcohol (ethanol), plays a mediating role in the brain damage associated with the chronic consumption of this substance.

DEVELOPMENT

Although the brain damage associated with the chronic consumption of ethanol is multifactorial and, possibly, dependent on the numerous actions of this substance on the central nervous system (CNS), there is data to suggest that the oxidative metabolism of ethanol and resulting substances are involved in the aetiology of such processes. Similarly, the generation of free radicals and the formation of adducts between the products of this metabolism and substrates contained in the CNS could be the main mediators in such pathological processes. This idea is supported by the fact that the adducts derived from the metabolism of ethanol are formed in the same areas of the brain as those which present structural and functional disorders in chronic consumers of alcohol.

CONCLUSIONS

There are currently different experimental findings that appear to support the proposal that the substances resulting from the metabolism of ethanol can be important mediators in the brain damage associated with the chronic consumption of alcohol. Although more research is required, this theoretical proposal is very interesting, not just because of its relative novelty, but also because it is based on the same principles put forward to explain the toxic effects of alcohol consumption on organs and tissues.

Neonatal administration of monosodium glutamate prevents the development of ethanol- but not psychostimulant-induced sensitization: a putative role of the arcuate nucleus

Lesions of the arcuate nucleus by monosodium glutamate, goldthioglucose and oestradiol valerate treatments are known to prevent the acute stimulating effect of ethanol in mice. On the basis of these results, the current study analysed whether a lesion of the arcuate nucleus by monosodium glutamate was able to block ethanol-induced locomotor sensitization. To produce the arcuate nucleus lesions, pups were injected with saline or monosodium glutamate (4 mg/g body weight) subcutaneously on 5 alternate days, starting on postnatal day one. Sensitization treatments began 10 weeks after the initial lesions. Sensitization training consisted of six trials on alternate days, in which groups of mice were treated with ethanol (2 g/kg) or saline, and then tested in an open-field for the induction of locomotor activity. The present study demonstrated that animals with monosodium glutamate-induced lesions did not develop locomotor sensitization to ethanol. Different groups of mice were used to assay blood ethanol levels and to evaluate the effect of arcuate nucleus lesions on psychostimulant-induced locomotor sensitization. Sensitization to cocaine or amphetamine was spared in monosodium glutamate-pre-treated animals, although the lesion of arcuate nucleus reduced the sensitivity of mice to cocaine. Our findings therefore suggest that the arcuate nucleus may be critical for the neuroadaptations that underlie the behavioural sensitization to ethanol, in contrast to those mediating psychostimulant-induced sensitization.

Ethanol-stimulated behaviour in mice is modulated by brain catalase activity and H2O2 rate of production

RATIONALE

Over the last few years, a role for the brain catalase-H(2)O(2) enzymatic system has been suggested in the behavioural effects observed in rodents after ethanol administration. This role seems to be related to the ability of cerebral catalase to metabolise ethanol to acetaldehyde using H(2)O(2)as a co-substrate. On the other hand, it has been shown that normobaric hyperoxia increases the rate of cerebral H(2)O(2) production in rodents in vivo. Thus, substrate-level changes could regulate brain catalase activity, thereby modulating the behavioural effects of ethanol.

OBJECTIVES

The aim of the present study was to assess if the enhancement of cerebral H(2)O(2) production after hyperoxia exposure results in a boost of ethanol-induced locomotion in mice.

METHODS

CD-1 mice were exposed to air or 99.5% O(2) inhalation (for 15, 30, or 45 min) and 0, 30, 60 or 120 min after this treatment, ethanol-induced locomotion was measured. The H(2)O(2)-mediated inactivation of endogenous brain catalase activity following an injection of 3-amino-1,2,4-triazole was used as a measure of the rate of cerebral H(2)O(2) production.

RESULTS

Hyperoxia exposure (30 or 45 min) potentiated the locomotor-stimulating effects of ethanol (2.5 or 3.0 g/kg), whereas cocaine (4 mg/kg) or caffeine (15 mg/kg)-induced locomotion and blood ethanol levels were unaffected. Moreover, the results also confirmed brain H(2)O(2) overproduction in mice.

CONCLUSIONS

The present results suggest that an increase in brain H(2)O(2) production potentiates ethanol-induced locomotion. Therefore, this study provides further support for the notion that the brain catalase-H(2)O(2) system, and by implication centrally formed acetaldehyde, plays a key role in the mediation of ethanol's psychopharmacological effects.

Consequences of monosodium glutamate or goldthioglucose arcuate nucleus lesions on ethanol-induced locomotion

It has been suggested that the endogenous opioid system, especially beta-endorphins, may play an important role in the behavioral effects of ethanol. The main site of beta-endorphin synthesis in the brain is the hypothalamic arcuate nucleus (ARC). In the present study, we used the neurotoxins monosodium glutamate (MSG) or goldthioglucose (GTG) to produce a selective ARC lesion and to assess its effects on the locomotion observed after ethanol administration. The results show that MSG or GTG pre-treatment produces a blockade of the increased locomotion produced by the injection of low and moderate doses of ethanol (0.5 and 1.5 g/kg, respectively). These effects were observed in the absence of any change in blood ethanol levels. On the other hand, MSG (but not GTG) pre-treatment enhanced the locomotor depression produced by higher doses of this alcohol (2.5 g/kg). Finally, caffeine (10 mg/kg)-induced locomotion was unaffected by the aforementioned neurotoxic agents. Thus, taken together, the present results suggest that MSG and GTG administration produce a blockade of the stimulating effects of ethanol on locomotion in mice and thus provides further support for a role of the ARC in the behavioral effects observed after ethanol administration.

Brain catalase inhibition blocks ethanol-related decrease of blood luteinizing hormone levels in mice

BACKGROUND

It has been demonstrated that ethanol decreases blood luteinizing hormone (LH) levels in rodents. This effect seems to be produced by the capacity of ethanol to release beta-endorphins from the hypothalamic arcuate nucleus and, in a second step, by a mu-receptor-mediated inhibitory effect of these peptides on hypothalamic LH-releasing hormone-synthesizing neurons. However, it has been reported that, in primary hypothalamic cultures, the ethanol-produced beta-endorphin release is mediated by the enzyme catalase. Therefore, the aim of this study was to assess whether catalase inhibition modifies ethanol effects on blood LH levels.

METHODS

Swiss albino mice were pretreated with the catalase inhibitor 3-amino-1,2,4-triazole (AT; 0.0-0.5 g/kg) and, 3.5 hr later, saline, ethanol (2.5 g/kg), or morphine (30 mg/kg) was administered. Blood samples were collected 2 hr after ethanol administration, and LH levels were immunoenzymatically assayed.

RESULTS

The catalase inhibitor AT dose-dependently blocked the ethanol-produced decrease in blood LH levels without altering those observed after saline or morphine administration. This effect was highly correlated with the decrease in brain catalase activity produced by AT.

CONCLUSIONS

These results show an antagonistic effect between AT and ethanol on blood LH levels and suggest a role of brain catalase activity on this effect of ethanol. Data are discussed in terms of a possible functional relationship between brain catalase and beta-endorphins in the mediation of some of the psychopharmacological consequences observed after ethanol administration.

Influence of brain catalase on ethanol-induced loss of righting reflex in mice

The effect of lead acetate and 3-amino-1, 2, 4-triazole (AT) on ethanol-induced loss of righting reflex (LORR) and brain catalase activity was studied in an attempt to confirm earlier observations on the involvement of catalase in ethanol-induced effects. Lead acetate (0 or 100 mg/kg) or AT (0 or 500 mg/kg) was injected (acutely) into mice 7 days or 5 h before testing. Other mice were exposed to drinking fluid containing 500 ppm lead acetate for 60 days. On the test day, mice received an intraperitoneal injection of ethanol (4.0 or 4.5 g/kg) and the duration of LORR was recorded. Acute lead-treated animals demonstrated a reduction in the duration of the LORR. However, both chronic administration of lead acetate and AT treatment increased the duration of ethanol-produced LORR. Furthermore, brain catalase activity in acute lead pretreated animals showed a significant induction, whereas it was reduced in chronic lead and AT treated mice. These results suggest that brain catalase activity, and by implication centrally formed acetaldehyde, may modulate ethanol-induced LORR.

Brain catalase activity is highly correlated with ethanol-induced locomotor activity in mice

It has been demonstrated that acute administration of lead to mice enhances brain catalase activity and ethanol-induced locomotion. These effects of lead seem to be related, since they show similar time courses and occur at similar doses. In the present study, in an attempt to further evaluate the relation between brain catalase activity and lead-induced changes in ethanol-stimulated locomotion, the interaction between lead acetate and 3-amino-1H,2,4-triazole (AT), a well-known catalase inhibitor, was assessed. In this study, lead acetate or saline was acutely injected intraperitoneally to Swiss mice at doses of 50 or 100 mg/kg 7 days before testing. On the test day, animals received an intraperitoneal injection of AT (0, 10, or 500 mg/kg). Five hours following AT treatment, ethanol (0.0 or 2.5 g/kg, ip) was injected and the animals were placed in open-field chambers, in which locomotion was measured for 10 min. Neither lead exposure nor AT administration, either alone or in combination, had any effect on spontaneous locomotor activity. AT treatment reduced ethanol-induced locomotion as well as brain catalase activity. On the other hand, ambulation and brain catalase activity were significantly increased by both doses of lead. Furthermore, AT significantly reduced the potentiation produced by lead acetate on brain catalase and on ethanol-induced locomotor activity in a dose-dependent manner. A significant correlation was found between locomotion and catalase activity across all test conditions. The results show that brain catalase activity is involved in the effects of lead acetate on ethanol-induced locomotion in mice. Thus, this study confirms the notion that brain catalase provides the molecular basis for understanding some of the mechanisms of the action of ethanol in the central nervous system.

Lession on the hypothalamic arcuate nucleus by estradiol valerate results in a blockade of ethanol-induced locomotion

It has been suggested that the endogenous opioid system, especially b-endorphins (b-ep), can play a key role in the behavioral effects of ethanol. A single injection of estradiol valerate (EV) produces a neurotoxic effect on the b-endorphin cell population of the hypothalamic arcuate nucleus. In the present study we questioned whether mice pretreated with EV, exhibit any alterations in ethanol-induced behavioral effects. Female Swiss mice were pretreated with EV (2 mg/0.2 ml per mice) or vehicle and, 8 weeks later, these animals were challenged with ethanol (0.0-3.2 g/kg). Immediately after ethanol injection, mice were placed in the open field chambers and locomotor activity was assessed. EV administration did not produce any change in spontaneous locomotor activity but, conversely, blocked the locomotor activity induced by low (0.8 g/kg) and moderate (1.6 or 2.4 g/kg) doses of ethanol. Interestingly, the behavioral effects of higher doses of ethanol on locomotor activity as well as on the duration of the loss of righting reflex were unaffected by EV. Moreover, neither rota-rod performance or blood ethanol levels were affected by EV. In a second study, the effects of EV pre-treatment on caffeine- and 1-propanol-induced locomotor activity was tested. No differences were observed between groups in caffeine- or 1-propanol-induced locomotion. The results of the present study indicate that EV blocks ethanol-induced locomotor activity and that this effect can not be related with any difference in ethanol levels or nonspecific motor impairment. Furthermore, they suggest that b-ep containing neurons of the hypothalamic arcuate nucleus may play a role in some, but not all, behavioral effects of ethanol.

Daily injections of cyanamide enhance both ethanol-induced locomotion and brain catalase activity

A role for brain catalase in the mediation of some psychopharmacological effects of ethanol has been proposed. In the present study, we investigated the effects of repeated cyanamide injections on the activity of brain catalase, as well as on the ethanol-induced locomotion of mice. Male Swiss mice were pre-treated with cyanamide (10 mg/kg; three times per day, 5 days) or saline. At different times (2, 3, 6 or 9 days) following this treatment, animals were injected with ethanol. Immediately following this ethanol challenge, animals were placed in the open field chambers and locomotor activity was assessed for 10 min. Results indicated an increase in ethanol-induced locomotion of mice pre-treated with cyanamide 2, 3 or 6 days before the ethanol challenge. Brain catalase activity showed an enhancement at the same time period and the two variables showed a significant correlation. No differences between pre-treatment groups on ethanol blood levels were observed at time of testing. In a second study, the effects of these cyanamide treatment conditions on d-amphetamine-induced locomotor activity were assessed. Results indicated no differences between pre-treatment groups in d-amphetamine-induced locomotion. Thus, these data suggest that repeated daily injections of cyanamide can simultaneously induce both brain catalase and locomotor activity, and that these effects may be strongly related. Furthermore, the present study provides further support for the notion that brain catalase activity may be a factor mediating some of the psychopharmacological effects of ethanol.

Effects of chronic lead administration on ethanol-induced locomotor and brain catalase activity

Several reports have demonstrated that chronic lead administration decreases brain catalase activity in animals. Other reports have shown a role of brain catalase on ethanol-induced behaviors. In the present study, we questioned whether mice treated chronically with lead, and therefore functionally devoid of brain catalase activity, exhibit some alterations in ethanol-induced behaviors. Swiss-Webster mice were exposed to drinking fluid containing either 500 ppm lead acetate or sodium acetate (control group) for 0, 15, 30, or 60 days before an acute ethanol administration. Following ethanol injection (2.5 g/kg, i.p.), animals were placed in open field chambers and locomotor activity was measured. Lead exposure had no effect on spontaneous locomotor activity. However, a reduction in ethanol-induced locomotor activity was found at all periods of lead exposure. After 60 days of treatment, the lead group demonstrated 35% less activity than the control group. Brain catalase activity was significantly reduced in the lead group following 60 days of exposure. This reduction in ethanol-induced locomotor activity and in brain catalase activity persisted after 40 days of lead withdrawal. The fact that brain catalase and ethanol-induced locomotor activity followed a similar pattern could suggest a relationship between both lead acetate effects and also a role for brain catalase in ethanol-induced behaviors.

The catalase inhibitor sodium azide reduces ethanol-induced locomotor activity

The involvement of brain catalase in modulating the psychopharmacological effects of ethanol was investigated by examining ethanol-induced locomotor activity in sodium azide-treated mice. Mice were pretreated with i.p. injections of the catalase inhibitor sodium azide (5, 10, or 15 mg/kg) or saline. Following this treatment, animals received i.p. injections of ethanol (0.0, 1.6, 2.4, or 3.2 g/kg). Ten minutes after ethanol administration, locomotor activity was recorded during a 10-min testing period in open-field chambers. The time effect between the two treatments (0, 30, 60, or 90 min) was also evaluated. Results indicated that sodium azide alone did not change spontaneous locomotor activity. However, this catalase inhibitor significantly reduced ethanol-induced locomotor activity when it was injected simultaneously or 30 min before ethanol injections. Moreover, perfused brain homogenates of mice treated with sodium azide also showed a significant reduction of catalase activity. No differences in blood ethanol levels were observed between sodium azide and saline pretreated animals. Results of an additional experiment showed that sodium azide (10 mg/kg, at 30 min) did not produce an effect on d-amphetamine- (2 mg/kg) or tert-butanol- (0.5 g/kg) induced locomotor activities. A specific interaction between ethanol and sodium azide at the level of the central nervous system is suggested. These results provide further support for the involvement of brain catalase in ethanol-induced behavioral effects. They also support the notion that acetaldehyde may be produced directly in the brain by catalase and that it may be an important regulator of ethanol's locomotor effects.

The ethanol-induced open-field activity in rodents treated with isethionic acid, a central metabolite of taurine

The effect of isethionic acid, a central metabolite of taurine, on ethanol-induced locomotor activity was investigated in rodents. Ten minutes following an (i.p.) simultaneous administration of ethanol (0.0, 1.5, 2.0, 2.5, 3.0, 3.5 g/kg) and isethionic acid (0.0, 22.5, 45.0, 90.0, 180.0 mg/kg), mice were placed in the open-field chambers and locomotor activity was measured during a ten-minute testing period. A significant interaction was found between isethionic acid and ethanol. Isethionic acid pre-treated mice (45.0, 90.0 and 180.0 mg/kg) showed a higher locomotor activity than the saline group at 2.5 and 3 g/kg of ethanol. In a second study, isethionic acid (45 mg/kg) and ethanol (1 g/kg) were simultaneously injected to rats. Ten minutes after the two treatments, rats were placed in the open-field chamber for a 30-minute period. The depressant effects that ethanol produced on rat locomotion were amplified by the same dose of isethionic acid as it affected ethanol-induced locomotion in mice (45 mg/kg). However, isethionic acid did not change the spontaneous locomotion at any of the doses tested in mice or rats. Since no differences in blood ethanol levels were detected in both mice and rats, the interaction between isethionic acid's action and ethanol-related locomotion does not seem to be due to different rates of absorption of ethanol or any other pharmacokinetic process related to ethanol levels. The current study displayed that isethionic acid, administered intraperitoneally, behaves in a similar way to its immediate precursor, taurine, by amplifying ethanol-induction of the locomotor activity.

Acute lead acetate administration potentiates ethanol-induced locomotor activity in mice: the role of brain catalase

It has been proposed that brain catalase plays a role in the modulation of some psychopharmacological effects of ethanol. The acute administration of lead acetate has demonstrated a transient increase in several antioxidant cell mechanisms, including catalase. In the present study, we investigated the effects of acute lead acetate administration on ethanol-induced behavior, brain catalase activity, and the relation between both effects. Lead acetate (100 mg/kg) or saline was injected intraperitoncally in mice. At different intervals of time (1, 3, 5, 7, 9, or 11 days) after this treatment, ethanol (2.5 g/kg) was injected intraperitoneally and the mice were placed in open field chambers. Results indicated that the locomotor activity induced by ethanol was significantly increased. Maximum ethanol-induced locomotion increase (70% more activity than control animals) was found in animals treated with lead acetate 7 days before ethanol administration. Total brain catalase activity in lead-pretreated animals also showed a significant induction, which was maximum 7 days after lead administration. A significant correlation was found between both effects of locomotor and catalase activity. In a second study, the effect of lead administration on d-amphetamine (2.0 mg/kg) and tert-butanol-(0.5 g/kg) induced locomotor activity was investigated. Lead acetate treatment did not affect the locomotion induced by these drugs. These data suggest that brain catalase is involved in ethanol's effects. They also provide further support for the notion that acetaldehyde may be produced directly in the brain via catalase and that it may be a factor mediating some of ethanol's central effects.

Cyanamide reduces brain catalase and ethanol-induced locomotor activity: is there a functional link?

The present study was designed in an attempt to assess a previously suggested role of brain catalase activity in ethanol-induced behaviour by examining ethanol-induced locomotor activity in cyanamide-treated mice. Mice were pretreated with IP injections of the catalase inhibitor cyanamide (3.75, 7.5, 15, 30 or 45 mg/kg) or saline. Following this treatment, animals in each group received IP injections of ethanol (0.0, 1.6, 2.4 or 3.2 g/kg) and locomotion was recorded. Several time intervals (0, 5, 10, 15, 20 or 25 h) between the two treatments were also evaluated. Results indicated that cyanamide administration produced a dose-dependent decrease in ethanol-induced locomotor activity that depends on the time between treatments. However, cyanamide did not change spontaneous or d-amphetamine-induced locomotor activity. Moreover, an additive effect of cyanamide and another brain catalase inhibitor, 3-amino-1,2,4-triazole (AT), on the reduction of ethanol-induced locomotor activity was observed. Perfused brain homogenates of mice treated with cyanamide, AT or cyanamide+AT showed a significant reduction of brain catalase activity. The dose and time patterns of both effects were closely related and a significant correlation between them was obtained. These results suggest that cyanamide could reduce locomotor activity through its inhibition of brain catalase, giving further support to the notion that brain catalase may be an important regulator of some ethanol-induced behavioural effects.