Dopamine receptor gene expression in an animal model of 'behavioral dependence' on ethanol.

The steady-state levels of messenger RNA (mRNA) of five cloned dopamine (D) receptors were measured in five brain regions in rats in a recently developed animal model of 'behavioral dependence' on ethanol. One group of rats was given the choice between ethanol and water over a 9-month period and developed 'behavioral dependence' on ethanol (group a). This group was compared with a group given the choice between ethanol and water for only 2 months (not yet behaviorally dependent, group b), a group forced to consume ethanol as sole fluid over a 9-month period (not behaviorally dependent, group c) and ethanol-naive control rats. All groups were sacrificed 1 month after ethanol withdrawal. The concentrations of mRNA of D3-receptors in the limbic forebrain (which included the nucleus accumbens) were significantly lowered in groups a and b, but unchanged in group c. D3 mRNA levels were reduced in the hippocampus of group b and unchanged in the cortex, amygdala and striatum. No significant changes in the mRNA concentrations of D1-, D2-, D4- or D5-receptors were seen in the five brain regions in any group. In conclusion, chronic consumption of ethanol under the 'free-choice condition', which may best induce the drug-rewarding effect, leads to specific changes in the D3-receptor gene expression which were not seen after forced ethanol administration. Changes in D3 mRNA levels were, however, not a specific correlate of 'behavioral dependence', as they were also detected in rats not yet 'behaviorally dependent' (group b).

Pharmacological dissociation between the reinforcing, sensitizing, and response-releasing functions of reward in honeybee classical conditioning.

Reserpine depletes biogenic amines from their stores in the honeybee (Apis mellifera carnica) brain and leads to impaired appetitive conditioning using sucrose as a reinforcer. Compensatory injection of octopamine or dopamine directly into the brain restores these behavioral losses. Dopamine rescues the slowing-down effect on motor patterns, but not sensitization or conditioning. Octopamine leaves the motor patterns as well as sensitization unchanged but rescues conditioning. Specifically, octopamine rescues acquisition but not retrieval. Serotonin has no significant effect on sensitization but impairs conditioning. The authors conclude that octopamine is involved in selectively mediating the reinforcing but not the sensitizing or response-releasing function of the sucrose reward, whereas dopamine is selectively involved in the expression of the motor response.

The development of addiction to d-amphetamine in an animal model: same principles as for alcohol and opiate.

We have established a rat model that reflects the course of development of alcohol and opiate addiction. The present study with d-amphetamine aimed to define general principles in the development of an addiction. Male rats had a continuous free choice between d-amphetamine solutions (100, 200 and 400 mg/l) and water for 47 weeks. An initial intake of high doses of d-amphetamine during the first weeks of drug choice was followed by an individually stable pattern of drug consumption of moderate drug doses. During this period of controlled consumption (from week 10 to week 40), the voluntary intake of d-amphetamine depended on individual factors (dominant rats: 0.37+/-0.02 mg/kg per day, subordinate rats: 0.57+/-0.05 mg/kg per day) and environmental variables (group housing: 0.21+/-0.02 mg/kg per day, single housing: 0.41+/-0.03 mg/kg per day). Beginning with week 41, voluntary d-amphetamine consumption progressively increased (1.9+/-0.2 mg/kg per day in week 47), although the experimental conditions remained unchanged. Drug intake during a retest (free choice as before) after 6 months of drug deprivation revealed that the rats had persistently lost their control over drug intake and were no longer able to adjust drug taking to internal and external conditions. These addicted rats took very high drug doses, even when all d-amphetamine solutions but not water were adulterated with bitter tasting quinine (6.6+/-0.6 mg/kg per day; age-matched controls: 0.37+/-0.04 mg/kg per day). Forced intake of d-amphetamine for 47 weeks (7.1+/-0.3 mg/kg per day) via the drinking fluid caused physical dependence (hyperreactivity during withdrawal) but did not lead to drug addiction (voluntary intake in the retest with adulteration: 0.42+/-0.04 mg/kg per day). Both the temporal development and the prerequisites of psychostimulant addiction were in principle the same as for alcohol and opiates.

From controlled drug intake to loss of control: the irreversible development of drug addiction in the rat.

The development of drug taking from controlled intake to drug addiction was studied by means of an animal model. Outbred rats had continuous free access to water and drinking fluids containing different concentrations of a drug for 7-9 months. After an abstinence period of 4-9 months, the drug was offered again (retest). Previous ethological classification of each rat and changes of housing conditions were used to study the modifiability of drug taking. With ethanol and the mu-agonistic opiate etonitazene, two stages followed each other. Controlled drug intake was adjusted to situational and individual variables. Social isolation of the rats raised the intake of ethanol and opiate. Dominant rats took less drugs than subordinate ones, but, in contrast to the latter, increased drug consumption after social disturbances. The adjustment of drug taking to social variables, was accompanied by changes in the dopaminergic and GABAA-ergic neurotransmission and by altered responses to acute drug administrations. Further, place preference, associated with reinforcing stimuli was modulated by subchronic sensitization/desensitization of dopaminergic transmission. Controlled drug intake lasted for 6-8 months, after which a spontaneous increase of drug consumption was found which latently continued during abstinence periods of 1 month. In the retest after abstinence, drug intake of these rats was strongly increased compared with both their previous consumption and that of drug-naive controls. Since drug taking could no longer be modulated by gustatory, environmental or individual factors (loss of control), it was considered as addictive. Addiction appeared to be specific to the kind of the drug. It persisted for the rest of the rat's life. After long periods of abstinence, ethanol-addicted rats revealed a completely altered pattern of response to self-administered alcohol compared with controlled drinkers. Their dopaminergic D1-transmission was irreversibly altered. Drug addiction only developed when the rat had free choice between water and drug-containing solutions. Long-term forced administration of ethanol or opiate, only led to physical dependence bot not to addiction. Some applications of the animal model are discussed, concerning the assessment of risk factors, the intake of drug combinations, residual neurochemical changes and concepts of treatment.

The development of opiate addiction in the rat.

Opiate intake was studied in rats, which were given free choice between water and etonitazene (ETZ) solutions (2, 4, and 8 mg/l) for 30 weeks. After an abstinence of 19 weeks, the opiate was reoffered. The long-term course of intake could be subdivided in three phases: a period of controlled intake (25 weeks), a period of increasing consumption (week 25-30), and the stage of drug addiction (retest). During controlled intake, environmental and individual variables reversibly influenced ETZ intake (high intake in socially deprived and in subordinate rats, low intake in group-housed and in dominant rats). After 25 weeks of situation-specific intake, the rats spontaneously increased ETZ consumption. In the retest after long-term ETZ-abstinence, their intake was strongly increased compared to both their own intake before and to that of drug-naive controls. ETZ intake could no longer be influenced by environmental, gustatory, or individual factors ("loss of control") indicating opiate addiction. In contrast, rats that have formerly had forced administration by means of a 2 mg/l ETZ solution did not become addicted. Signs of opiate withdrawal, however, occurred in both series of forced and voluntary intake. Principles of the temporal development of opiate addiction are compared with those described previously for ethanol addiction.

Social behavior, dominance, and social deprivation of rats determine drug choice.

Relationships between social deprivation, dominance, and voluntary intake of ethanol (ETOH) and diazepam (D) were studied in male adult Wistar rats. Social behavior was registered by tetradic encounters in the open field prior to the rats' drug experiences. Social deprivation was induced by individual housing (LI) and contact caging (C). Nondeprived rats were housed in groups of four individuals (G) each. Social deprivation facilitated ETOH intake: LI rats consumed 30% more ETOH than G. Increase of deprivation by change of housing condition additionally raised ETOH consumption. ETOH experiences did not affect subsequent D choice. However, rats with a high ETOH consumption also preferred D. Individual drug disposition correlated with social dominance (in G: to social activity). Even in individual isolation dominant rats took less drugs than subordinate ones, but these rats raised their ETOH consumption when the housing conditions were changed. After nine months of voluntary ETOH intake and subsequently nine months without access to ETOH the rats showed signs of "behavioral dependence." Compared to naive animals they took twice as much ETOH and even after adulterating ETOH by quinine a high preference was perpetuated. During this state modifying social factors were no longer effective.

Persisting consequences of drug intake: towards a memory of addiction.

Long-term intake of a psychoactive drug alters brain signal transduction, emotional and motivational factors and behavioral parameters. Some effects that outlast long periods of abstinence are due to the long-term presence of the drug in the organism (tolerance, physical dependence). Withdrawal symptoms, as a consequence of physical dependence, can be protracted, i.e. they persist after long periods of drug deprivation (e.g. a desensitization of the production of cAMP). Further persisting effects include experience-based learning. At least three distinct processes can be differentiated: a memory of drug effects (reflected by a sensitization to drug effects etc.), a memory of drug use (reflected by controlled drug consumption), and a memory of addiction (reflected by a persisting loss of control over drug intake and correlating changes in striatal dopaminergic neurotransmission). The latter probably consists of two components: a general memory of loss of control and a specific memory of the addictive drug (general principles for the development of addiction, specific of the urge for the addictive drug).

Animal models of addiction: models for therapeutic strategies?

When having a continuous free choice in their home cages between water and alcohol- or drug-containing drinking solutions, rats first develop a controlled consumption of the psychotropic compound and, after several months, lose their control over drug taking. After a long period of abstinence, they reveal an excessive, compulsive drug intake. Adulteration of the drug-containing solutions reduces the doses taken by controlled consumers, but not those of the excessive drinkers, they can therefore be regarded as addicted. These animals show a pre-intake motor restlessness that may be related to craving. In two studies with putative anti-craving agents (the dopamine D2 receptor agonist lisuride and the D2 receptor antagonist flupentixol) we treated alcohol-addicted and non-addicted rats and observed the effects on alcohol taking, alcohol seeking and brain neurotransmission. These two investigations paralleled clinical studies, in both cases the results could be predicted correctly ("pro-craving" effect of both pharmaceutics). Differences between "symptomatic" and possible "causal" therapies are discussed, approaches towards a causal therapy according to an "imprinting"-model of an addition are suggested.

Hypothalamic-pituitary-thyroid axis in chronic alcoholism. II. Deiodinase activities and thyroid hormone concentrations in brain and peripheral tissues of rats chronically exposed to ethanol.

Thyroxine (T4), triiodothyronine (T3) concentrations, and the activities of the three deiodinase isoenzymes were measured in different brain regions and peripheral tissues of rats. According to an animal model of alcohol addiction, "behaviorally" dependent rats having lost control over their intake of ethanol were compared with alcohol-naive controls and ethanol-experienced, but "controlled" consumers. The two kinds of alcohol-experienced rats were investigated either 24 hr or 3 months after ethanol withdrawal. The results of these four groups were compared with those of an ethanol-naive control group. During withdrawal, the activities of type II 5'-deiodinase (which catalyzes deiodination of T4 and T3 in the CNS) in both the "behaviorally dependent" rats and the "controlled drinkers" were significantly lower than in the alcohol-naive controls in the frontal cortex, parieto-occipital cortex, hippocampus, and striatum, but not in the cerebellum or pituitary. Probably as a result, the tissue concentrations of T4 were higher in areas of the CNS in the groups exposed to alcohol. However, the T3 concentrations were normal. No relevant differences were seen between the activities of type III 5-deiodinase (which catalyzes the further deiodination of T3) observed in these groups. After 3 months of abstinence, the type II 5'-deiodinase activities had almost returned to normal in both "controlled drinkers" and "behaviorally dependent" animals, whereas type III 5-deiodinase activity was inhibited, possibly to maintain physiological concentrations of T3 during abstinence. Indeed, the tissue levels of T3 were normal in the areas of the CNS, and the T4 levels were still elevated. However, the liver concentrations of T3 and T4 were significantly lower in the "behaviourally dependent" animals than in the "controlled" drinkers after 3 months of abstinence, whereas no differences were found between the T4 and T3 concentrations in the areas of the CNS investigated in the two groups exposed to ethanol. These results suggest that chronic administration of ethanol affects intracellular thyroid hormone metabolism in both rat CNS and liver in the highly complex manner. No direct evidence of ethanol-induced enhancement of tissue uptake or concentrations was obtained. However, taking into account the numerous similarities between the clinical picture of hyperthyroidism and the symptomatology of alcoholism, it may be hypothesized that ethanol may directly influence any step in the as yet unknown biochemical cascade of thyroid hormone function.