Brain locations controlling the behavioral effects of chronic amphetamine intoxication

Development and persistence of methamphetamine-conditioned hyperactivity in Swiss-Webster mice

These experiments examined the development and persistence of methamphetamine-conditioned hyperactivity in Swiss-Webster mice. Experiments 1 and 2 examined the development of conditioned hyperactivity, varying the methamphetamine dose (0.25-2.0 mg/kg), the temporal injection parameters (continuous; experiment 1 or intermittent; experiment 2), and the comparison control group (saline; experiment 1 or unpaired; experiment 2). Experiment 3 examined the persistence of methamphetamine-conditioned hyperactivity by comparing mice 1 (immediate) or 28 (delay) days after drug withdrawal. In each experiment, several behavioral measures (vertical counts, distance traveled, and velocity) were recorded and temporal analyses conducted to assess methamphetamine-conditioned hyperactivity. In experiments 1 and 2, it was found that methamphetamine-conditioned hyperactivity was (i) dose-dependent, (ii) detected early in the session, and (iii) detected by a behavioral measure indicative of general activity (i.e. distance traveled), and (iv) varied as a function of the number of conditioning sessions. In experiment 3, it was found that conditioned hyperactivity persisted for 28 days, though was weakened by nonassociative factors, following methamphetamine withdrawal. Collectively, these results suggest that conditioned hyperactivity to methamphetamine is robust and persists after prolonged periods of drug withdrawal in mice. Furthermore, these results are consistent with an excitatory classical conditioning interpretation of conditioned hyperactivity.

Cholinergic depletion in the nucleus accumbens: effects on amphetamine response and sensorimotor gating

A delicate balance between dopaminergic and cholinergic activity in the ventral striatum or nucleus accumbens (N.Acc) appears to be important for optimal performance of a wide range of behaviours. While functional interactions between these systems are complex, some data suggest that acetylcholine in the N.Acc. may dampen the effects of excessive dopamine (DA) release. We proposed that a reduction in the density of cholinergic interneurons in the N.Acc would result in behavioural alterations suggestive of a hyper-responsiveness of the N.Acc DA system. The present study aimed to produce a sustainable depletion of cholinergic neurons in the N.Acc in the rat and study the effects of such lesions on DA-dependent behaviour. A novel saporin immunotoxin targeting choline acetyltransferase was microinjected bilaterally into the N.Acc of adult rats. We confirmed histologically that two weeks post-injection, animals show a local, selective depletion of cholinergic interneurons (mean cell loss of 44%). Cholinergic-depleted rats showed a marked increase in the locomotor activating effects of amphetamine. In addition, such lesions induced a disruption of sensorimotor gating processes, reflected in a reduction in the prepulse inhibition of the acoustic startle response, which was reversed by haloperidol. These data are suggestive of pronounced hyper-responsiveness of the meso-accumbens DA system which may be of relevance to the pathophysiology of schizophrenia, a condition where selective reduction in the number of ventral striatal cholinergic neurons has been demonstrated.

Behavioral sensitization, alternative splicing, and d3 dopamine receptor-mediated inhibitory function

Behavioral sensitization, the progressive and enduring augmentation of certain behaviors following repetitive drug use, alters rodent locomotion in a long-standing manner. The same dopamine pathways playing an important role in drug dependence and psychosis also play a critical role in sensitization. Individual dopamine receptor subtypes have markedly different functional responses to stimulation, with D3 dopamine receptor stimulation inhibiting rodent locomotion. The D3 receptor has highest affinity of the dopamine receptor subtypes for dopamine, and is occupied to a greater degree following stimulant drug administration. D3 receptor activity may be regulated through the expression of an alternatively spliced, truncated receptor isoform (termed 'D3nf') altering receptor localization and function via dimerization with the full-length subunit. The expected physiological response to repetitive drug administration is tolerance. Tolerance of D3 receptor inhibition of locomotion would contribute to sensitization to stimulant drugs. We hypothesize that repetitive D3 receptor stimulation contributes to the development of behavioral sensitization through decreased responsivity of D3-receptor-mediated locomotor inhibition. Increased D3nf expression may direct altered receptor localization and subsequent release of D3-receptor-mediated inhibition, contributing to the expression of sensitization. These hypotheses follow directly from the affinities of the receptor subtypes for dopamine; dopamine concentrations following stimulant administration; the effects of individual dopamine receptor subtype stimulation on locomotion; and the expected homeostatic response of the system to perturbation by drug. Clarifying these mechanisms underlying sensitization may suggest new interventions for neuropsychiatric conditions in which dopamine plays an important role, including psychosis, drug dependence, and Parkinson's disease. This information may also elucidate a previously unrecognized mechanism regulating receptor trafficking and desensitization.

The role of age, genotype, sex, and route of acute and chronic administration of methylphenidate: A review of its locomotor effects

Children with attention deficit hyperactivity disorder (ADHD) are treated for extended periods of time with the psychostimulant methylphenidate (MPD). The psychostimulants cocaine, amphetamine, and MPD exhibit similar structural configuration and pharmacological profile. The consequence of the long-term use of psychostimulants such as MPD as treatment for ADHD in the developing brain of children is unknown. Repeated treatment with psychostimulants has been shown to elicit adverse effects in behavior, such as dependence, paranoia, schizophrenia, and behavioral sensitization. Behavioral sensitization and cross-sensitization between two drugs are used as experimental markers to determine the potential of a drug to develop dependence/addiction. Although there are many reviews written about behavioral sensitization involving psychostimulants, scarcely any have focused specifically on MPD-elicited behavioral sensitization and cross-sensitization with other psychostimulants. Moreover, the response to MPD and the expression of ADHD vary among females and males and among different populations due to genetic variability. Since the interpretation and synthesis of the data reported are controversial, this review focuses on the adverse effects of MPD and the role of age, sex, and genetic composition on the acute and chronic effects of MPD, such as MPD-elicited behavioral sensitization and cross-sensitization with amphetamine in animal models. Animal models of drug-induced locomotor stimulation, particularly locomotor sensitization, can be used to understand the mechanisms underlying human drug-induced dependence.

Altered behavioral response to dopamine D3 receptor agonists 7-OH-DPAT and PD 128907 following repetitive amphetamine administration

Behavioral sensitization, the progressive and enduring enhancement of certain behaviors following repetitive drug use, is mediated in part by dopaminergic pathways. Increased locomotor response to drug treatment, a sensitizable behavior, is modulated by an opposing balance of dopamine receptor subtypes, with D1/D2 dopamine receptor stimulation increasing and D3 dopamine receptor activation inhibiting amphetamine-induced locomotion. We hypothesize that tolerance of D3 receptor locomotor inhibition contributes to behavioral sensitization. In order to test the hypothesis that expression of behavioral sensitization results in part from release of D3 receptor-mediated inhibition, thereby resulting in decreased response to D3 receptor agonists, we examined the effect of repetitive amphetamine administration on the behavioral response to the D3 receptor preferring agonists 7-OH-DPAT and PD 128907. D3-selective effects have recently been described for both drugs at a low dose. At 1 week following completion of a repetitive treatment regimen, amphetamine-pretreated rats displayed a decreased response to D3-selective doses of both 7-OH-DPAT and PD 128907, when compared to animals receiving saline pretreatment. Moreover, in addition to the quantitative alteration in response, there was a change in the inter-relation between response to amphetamine and D3 agonist. A highly significant inverse relation between locomotor inhibitory response to PD 128907 and the locomotor-stimulant response to amphetamine was observed prior to amphetamine treatment. In contrast, 10 days following repetitive amphetamine treatment, the relation between response to PD 128907 and amphetamine was not detected. The observed behavioral alteration could not be accounted for by changes in D3 receptor binding in ventral striatum. These findings suggest a persistent release of D3 receptor-mediated inhibitory influence contributes to the expression of behavioral sensitization to amphetamine.

What we know and what we need to know about the role of endogenous CCK in psychostimulant sensitization

The unique distribution of CCK and its receptors and its co-localization with dopamine makes it ideally situated to pay a role in dopamine-mediated reward and psychostimulant sensitization. A number of studies support the hypothesis that CCK acting through the CCK 1 and CCK 2 receptors is an endogenous modulator of dopamine neurotransmission. Behavioral studies with CCK antagonists and CCK 1 receptor mutant rats support a role for endogenous CCK in behavioral sensitization to psychostimulants. CCK microdialysis studies in the nucleus accumbens (NAC) have demonstrated that extracellular CCK is increased in the NAC by psychostimulants, providing neurochemical evidence that CCK could be involved in the behavioral response to psychostimulants. A model for how CCK may be acting in multiple brain regions to foster sensitization is presented and the gaps in our knowledge about the role of CCK in psychostimulant sensitization are described.

Effects of fencamfamine on latent inhibition

The effects of fencamfamine (FCF), an indirect dopamine (DA) agent, were investigated using the latent inhibition (LI) model of schizophrenia. In the LI procedure, rats preexposed (PE) to an unreinforced stimulus show difficulty in subsequent learning of an association in which that stimulus is predictive of an unconditioned stimulus (US). FCF (1.75, 3.5 and 7.0 mg/kg i.p.) yielded an inverse dose-response relationship regarding LI. At 3.5 mg/kg, LI was abolished and no effect was observed at 1.75 and 7.0 mg/kg. The effect of FCF (3.5 mg/kg) on LI was blocked by the antipsychotic risperidone (RIS; 4.0 mg/kg), a D2/5HT2 antagonist. These results confirm the similarity of the behavioral profile of FCF and amphetamine (AMPH). In addition, they provide a further validation of the LI model for psychosis, since RIS was shown to prevent a psychostimulant-induced disruption of LI.

The role of neurotrophic factors in psychostimulant-induced behavioral and neuronal plasticity

Several neurotrophic factors influence the development, maintenance and survival of dopaminergic neurons in the mammalian central nervous system (CNS), including neurotrophin-3 (NT-3), brain derived neurotrophic factor (BDNF), ciliary neurotrophic factor (CNTF), basic fibroblast growth factor (bFGF) and glial derived neurotrophic factor (GDNF). This review focuses on the role of these neurotrophic factors in psychostimulant-induced behavioral sensitization, a form of dopamine-mediated neuronal plasticity that models aspects of paranoid schizophrenia as well as drug craving among psychostimulant addicts. Whereas NT-3, CNTF and bFGF appear to play a positive role in psychostimulant-induced behavioral sensitization, GDNF inhibits this form of behavioral plasticity. The role of BDNF in behavioral sensitization, however, remains elusive. While it has been shown that neurotrophic factors can influence the behavioral, structural and biochemical phenomena related to psychostimulant-induced neuronal plasticity, it is unclear which neurotrophic factors are important physiologically and which have purely pharmacological effects. In either case, examining the role of neurotrophic factors in behavioral sensitization may enhance our understanding of the mechanisms underlying the development of paranoid psychosis and drug craving and lead to the development of novel pharmacological treatments for these disorders.

Differential behavioral responses to chronic amphetamine in adult male and female rats exposed to postnatal cocaine treatment

The impact of cocaine exposure during development on behavioral sensitization as measured by locomotor activity and stereotypy following repeated intermittent administration of amphetamine is examined. Male and female Sprague-Dawley rats were exposed to cocaine at 50 mg/kg/day during postnatal days (PND) 11-20 and, as adults (PND193-212), were administered seven daily injections of 2.0 mg/kg amphetamine. Both locomotor activity and stereotypic behavior were assessed following the first and seventh injections. Control males and females showed sensitized behavior following repeated amphetamine injections with females showing greater locomotion while males showed increased stereotypy. Male rats pretreated with cocaine failed to develop sensitized locomotor or stereotypic responses following repeated amphetamine injections consistent with dampened D(1) receptor activity. Females pretreated with cocaine did not show a sensitized locomotor response but did display sensitization of stereotypy following repeated amphetamine administration. Thus, it appears that postnatal cocaine treatment produces differential effects on the circuits mediating sensitization behavior in male and female rats.

The role of excitatory amino acids in behavioral sensitization to psychomotor stimulants

Behavioral sensitization refers to the progressive augmentation of behavioral responses to psychomotor stimulants that develops during their repeated administration and persists even after long periods of withdrawal. It provides an animal model for the intensification of drug craving believed to underlie addiction in humans. Mechanistic similarities between sensitization and other forms of neuronal plasticity were first suggested on the basis of the ability of N-methyl-D-aspartate (NMDA) receptor antagonists to prevent the development of sensitization [Karler, R., Calder, L. D., Chaudhry, I. A. and Turkanis, S. A. (1989) Blockade of "reverse tolerance" to cocaine and amphetamine by MK-801. Life Sci., 45, 599-606]. This article will review the large number of subsequent studies addressing: (1) the roles of NMDA, alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate (AMPA) and metabotropic glutamate receptors in the development and expression of behavioral sensitization, (2) excitatory amino acids (EAAs) and the role of conditioning in sensitization, (3) controversies regarding EAA involvement in behavioral sensitization based on studies with MK-801, (4) the effects of acute and repeated stimulant administration on EAA neurochemistry and EAA receptor expression, and (5) the neuroanatomy of EAA involvement in sensitization. To summarize, NMDA, AMPA metabotropic glutamate receptors all participate in the development of sensitization, while maintenance of the sensitized state involves alterations in neurochemical measures of EAA transmission as well as in the expression and sensitivity of AMPA and NMDA receptors. While behavioral sensitization likely involves complex neuronal circuits, with EAAs participating at several points within this circuitry, EAA projections originating in prefrontal cortex may play a particularly important role in the development of sensitization, perhaps via their regulatory effects on midbrain dopamine neurons. The review concludes by critically evaluating various hypotheses to account for EAA involvement in the development of behavioral sensitization, and considering the question of whether EAA receptors are involved in mediating the rewarding effects of psychomotor stimulants and sensitization of such rewarding effects.

Kamin blocking is not disrupted by amphetamine in human subjects

The effect of oral amphetamine administration on the Kamin-blocking effect in healthy volunteer subjects was investigated. Against predictions, Kamin blocking was not disrupted by either a high or low oral dose of D-amphetamine under conditions which have, in previous studies, led to disruption of a related learning phenomenon (latent inhibition). This lack of effect of amphetamine administration upon Kamin blocking weakens hypotheses that this cognitive process is mediated by the same changes in dopaminergic activity which affect latent inhibition. Currently, the only data which show strong comparative associations between Kamin blocking and latent inhibition are when they are applied to schizophrenic populations. These results may suggest that Kamin blocking and latent inhibition may be measuring different aspects of schizophrenic cognitive dysfunction.

A circuitry model of the expression of behavioral sensitization to amphetamine-like psychostimulants

Repeated exposure to psychostimulants such as cocaine and amphetamine produces behavioral sensitization, which is characterized by an augmented locomotor response to a subsequent psychostimulant challenge injection. Experimentation focused on the neural underpinnings of behavioral sensitization has progressed from a singular focus on dopamine transmission in the nucleus accumbens and striatum to the study of cellular and molecular mechanisms that occur throughout the neural circuitry in which the mesocorticolimbic dopamine projections are embedded. This research effort has yielded a conglomerate of data that has resisted simple interpretations, primarily because no single neuronal effect is likely to be responsible for the expression of behavioral sensitization. The present review examines the literature and critically evaluates the extent to which the neural consequences of repeated psychostimulant administration are associated with the expression of behavioral sensitization. The neural alterations found to contribute to the long-term expression of behavioral sensitization are centered in a collection of interconnected limbic nuclei, which are termed the 'motive' circuit. This neural circuit is used as a template to organize the relevant biochemical and molecular findings into a model of the expression of behavioral sensitization.

Quantification of dopamine D1 and D2 receptor mRNA levels associated with the development of behavioral sensitization in amphetamine treated rats

We hypothesized that changes in expression of dopamine (DA) D1 and D2 receptor genes in caudate/putamen (CP) would correlate with the development of behavioral changes in amphetamine treated rats. In order to test this hypothesis, we measured DA D1 and D2 receptor mRNA in CP, as well as locomotor behavior, in individual rats following amphetamine treatment. D1 and D2 mRNA levels were similar in caudate/putamen of rats treated with acute amphetamine, chronic amphetamine or saline injection. We found no correlation between D1 or D2 mRNA levels in caudate/putamen and the behavioral response to either acute or chronic amphetamine. These results suggest that behavioral sensitization to amphetamine is not mediated through transcriptional regulation of D1 or D2 mRNA levels in caudate/putamen.

Acute sensitivity vs. context-specific sensitization to cocaine as a function of genotype

Individual variability in the acute and chronic effects of psychomotor stimulants is due, in part, to genetic factors. The purpose of this series of studies was to utilize a behavioral model of sensitization, namely increased locomotor activity, to assess individual variability in sensitization to the chronic effects of cocaine and its relationship to the acute stimulant effects of cocaine. Because the degree of sensitization is proportional to the training dose, genetic differences in acute sensitivity to cocaine were assessed and incorporated into the sensitization paradigm. Acute sensitivity and context-dependent sensitization were determined in six inbred mouse strains. Large quantitative and qualitative differences were found in the acute potency and efficacy of cocaine to stimulate locomotor activity. The ED50 was higher in the strains in which cocaine was most efficacious. Context-specific sensitization was determined via chronic administration of equiactive doses of cocaine (ED50) specifically paired with the test apparatus or with the home colony. Sensitization was time, environment, and genotype dependent. The differences in the number of trials required to show sensitization were unrelated to the acute locomotor stimulant effects of cocaine. These findings suggest that acute cocaine-induced locomotor activity and context-specific sensitization reflect different pharmacological properties of cocaine.

The role of mesolimbic dopaminergic and retrohippocampal afferents to the nucleus accumbens in latent inhibition: implications for schizophrenia

Latent inhibition (LI) consists in a retardation of conditioning seen when the to-be-conditioned stimulus is first presented a number of times without other consequence. Disruption of LI has been proposed as a possible model of the cognitive abnormality that underlies the positive psychotic symptoms of acute schizophrenia. We review here evidence in support of the model, including experiments tending to show that: (1) disruption of LI is characteristic of acute, positively-symptomatic schizophrenia; (2) LI depends upon dopaminergic activity; (3) LI depends specifically upon dopamine release in n. accumbens; (4) LI depends upon the integrity of the hippocampal formation and the retrohippocampal region reciprocally connected to the hippocampal formation; (5) the roles of n. accumbens and the hippocampal system in LI are interconnected.

Dopamine release in the nucleus accumbens: the perspective from aberrations of consciousness in schizophrenia

Studies of the cognitive abnormalities that underlie positive symptoms in acute schizophrenia, and animal experiments that attempt to model similar cognitive abnormalities and to elucidate the brain mechanisms underlying them, suggest that the release of dopamine from A 10 terminals in the nucleus (n.) accumbens, in interaction with the projection to n. accumbens from the retrohippocampal region, is closely related to stimulus salience and perhaps to the heightened states of awareness reported by schizophrenics.

Latent inhibition in drug naive schizophrenics: relationship to duration of illness and dopamine D2 binding using SPET

The dual aims of the study were (1) to examine the effect of neuroleptic medication on the expression of latent inhibition (LI) by studying LI in drug naive schizophrenic patients, and (2) to investigate the relationship between LI and dopamine D2 receptor binding in the basal ganglia using single photon emission tomography (SPET). Subjects constituted a sub-set of patients investigated in a major study of in vivo D2 receptor binding in schizophrenia (Pilowsky et al., 1993). Striatal D2 receptor binding was assessed in 15 neuroleptic naive schizophrenic patients and 13 healthy volunteers. The performance of subjects on a within-subject auditory latent inhibition paradigm was also assessed. There was found to be no significant difference in LI between schizophrenic patients and normal controls, both groups showing a strong within-subject LI effect. There was also found to be no association between LI and dopamine D2 receptor binding in either the left or the right basal ganglia. This lack of association indicates that LI is not directly related to post-synaptic D2 receptor levels in the striatum. LI was, however, found to be correlated with duration of illness in the schizophrenic group. Patients with a relatively short duration of illness (< 12 months) tended to show reversed, or absent, LI whereas patients with a longer illness duration (> 12 months) showed intact LI. The effect on LI of duration of illness is consistent with previous findings that LI is disrupted specifically in acute, but not chronic, schizophrenia. Previous studies have assumed that this pattern of results is due to the stabilising effect of long-term neuroleptic medication. The present findings in a sample of neuroleptic naive schizophrenic patients indicate that this is unlikely to be the case. Rather, it appears that the reinstatement of LI in schizophrenic patients over time is due to a factor(s) intrinsic to the evolution of the schizophrenic illness.

The role of dopamine in drug abuse viewed from the perspective of its role in motivation

Drugs of abuse share with conventional reinforcers the activation of specific neural pathways in the CNS that are the substrate of their motivational properties. Dopamine is recognized as the transmitter of one such neural pathway, being involved in at least three major aspects of motivation: modulation of motivational state, acquisition (incentive learning) and expression of incentive properties by motivational stimuli. Drugs of abuse of different pharmacological classes stimulate in the low dose range dopamine transmission particularly in the ventral striatum. Apart from psychostimulants, the evidence that stimulation of dopamine transmission by drugs of abuse provides the primary motivational stimulus for drug self-administration is either unconvincing or negative. However, stimulation of dopamine transmission is essential for the activational properties of drugs of abuse and might be instrumental for the acquisition of responding to drug-related incentive stimuli (incentive learning). Dopamine is involved in the induction and in the expression of behavioural sensitization by repeated exposure to various drugs of abuse. Sensitization to the dopamine-stimulant properties of specific drug classes leading to facilitation of incentive learning of drug-related stimuli might account for the strong control over behaviour exerted by these stimuli in the addiction state. Withdrawal from drugs of abuse results in a reduction in basal dopamine transmission in vivo and in reduced responding for conventional reinforcers. Although these changes are likely to be the expression of a state of dependence of the dopamine system their contribution to the motivational state of drug addiction is unclear.

R-(+)-HA-966, an antagonist for the glycine/NMDA receptor, prevents locomotor sensitization to repeated cocaine exposures

Repeated administration of cocaine results in a reverse tolerance or sensitization to the locomotor stimulant properties of cocaine. In this study, we examined the effect of an antagonist for the strychinine-insensitive glycine receptor of the NMDA receptor complex, R-(+)-HA-966, on the development of locomotor sensitization to cocaine. Co-administration of R-(+)-HA-966 with repeated cocaine prevented locomotor sensitization to a subsequent challenge dose of cocaine. However, R-(+)-HA-966 (15 mg/kg i.p.) did not attenuate locomotor activation to an acute dose of cocaine (15 mg/kg). These results indicate that the glycine/NMDA receptor is involved in locomotor sensitization to repeated cocaine administration but not in the locomotor activation to the acute stimulant effects of cocaine administration.

Correlation between behavioral sensitization to cocaine and G protein ADP-ribosylation in the ventral tegmental area

The ventral tegmental area is a site of action by psychostimulants in the production of behavioral sensitization. Recently, G proteins of the ventral tegmental area have been implicated in behavioral sensitization to cocaine. To further investigate the specific role of G proteins, rats were treated with either 15 or 30 mg/kg, i.p., of cocaine (x 5 days), and at 1, 6 or 24 h after the last injection in vitro pertussis toxin catalyzed adenosine diphosphate (ADP)-ribosylation was used to measure the G proteins in the ventral tegmental area, nucleus accumbens, prefrontal cortex, substantia nigra, and striatum. A significant decline in the ADP-ribosylation of G proteins, specific for the ventral tegmental area, was observed at 1 and/or 6 h but had returned to normal by 24 h. A significant negative correlation was found between the percent of G proteins ADP-ribosylated in the ventral tegmental area and the behavioral activity elicited in sensitized but not acute cocaine-treated animals at 1 h after injection. These data suggest that the G proteins ADP-ribosylated by pertussis toxin may be involved in the sensitized motor response produced by repeated cocaine administration in rats.

Abolition of latent inhibition by a single 5 mg dose of d-amphetamine in man

The performance of healthy volunteer subjects on an auditory latent inhibition (LI) paradigm was assessed following administration of a single oral dose of d-amphetamine or placebo. It was predicted that a low (5 mg), but not a high (10 mg), dose of d-amphetamine would disrupt LI. The prediction was supported with left ear presentation of the preexposed stimulus only. When the preexposed stimulus was presented to the right ear the predicted pattern of findings was not obtained. It is concluded that the dopaminergic system is involved in the mediation of LI in man and it is speculated that the interaction between amphetamine dose and ear of presentation of the preexposed stimulus may reflect normally occurring dopaminergic hemisphere asymmetry.

Dopamine transmission in the initiation and expression of drug- and stress-induced sensitization of motor activity

Progress has been made over the last 10 years in determining the neural mechanisms of sensitization induced by amphetamine-like psychostimulants, opioids and stressors. Changes in dopamine transmission in axon terminal fields such as the nucleus accumbens appear to underlie the expression of sensitization, but the actions of drugs and stressors in the somatodendritic regions of the A10/A9 dopamine neurons seem critical for the initiation of sensitization. Manipulations that increase somatodendritic dopamine release and permit the stimulation of D1 dopamine receptors in this region induce changes in the dopamine system that lead to the development of long-term sensitization. However, it is not known exactly how the changes in the A10/A9 region are encoded to permit augmented dopamine transmission in the terminal field. One possibility is that the dopamine neurons of sensitized animals have become increasingly sensitive to excitatory pharmacological and environmental stimuli or desensitized to inhibitory regulation. Alternatively, changes in cellular activity or protein synthesis may result in a change in the presynaptic regulation of axon terminal dopamine release.

Possible role for G-proteins in behavioral sensitization to cocaine

The role of G-proteins in behavioral sensitization to cocaine was examined by injecting pertussis toxin (PTX) into the A10 dopamine cell group. The capacity of acute cocaine to increase motor activity and dopamine release in the nucleus accumbens was significantly augmented in rats pretreated 14 days earlier with PTX. These data suggest that injection of PTX into the A10 dopamine cell group produces a long-term alteration in mesolimbic dopamine function, and implicates A10 dopamine neurons and G-proteins in the development of behavioral sensitization.

The utility of 1-[18F]fluoro-3-iodopropane for the synthesis of certain dopamine D-1 and benzodiazepine receptor radioligands

No-carrier-added (NCA) R(+)-7-chloro-8-hydroxy-3-(3'-[18F]fluoropropyl)-1-phenyl-2,3,4,5- tetrahydro-3-benzazepine (2b) (an analog of dopamine D-1 receptor ligand SCH 23390), ethyl 8-fluoro-5,6-dihydro-5-(3'-fluoropropyl)-6-oxo-4H- imidazo[1,5-a][1,4]benzodiazepine-3-carboxylate (4b) and 3'-[18F]fluoropropyl 8-fluoro-5,6-dihydro-5-methyl-6-oxo-4H- imidazo[1,5-a][1,4]benzodiazepine-3-carboxylate (6b) (analogs of the benzodiazepine RO 15-1788) were synthesized by alkylation of the corresponding nor-compound with NCA 1-[18F]fluoro-3-iodopropane in 10-15% yield (EOB) in approximately 110 min and with a mass of 2-3 nmol. Compound 2 is less potent (approximately 12-14 times) than SCH 23390 in binding to rat striatal membranes in vitro. Compounds 2b, 4b and 6b exhibit no specific anatomical distribution to mouse brain. These results suggest that the substituent at position 3 of SCH 23390, and position 5 and carboxylate group of RO 15-1788 are critical determinants both of affinity and selectivity for receptor binding, and underscores the evaluation necessary when even minor changes (C1 to C3) are made in bioactive compounds.

Disruption of latent inhibition by acute administration of low doses of amphetamine

In the latent inhibition (LI) paradigm, nonreinforced preexposure to a stimulus retards subsequent conditioning to that stimulus. Three experiments investigated the effects of acute amphetamine administration on LI in rats. Experiments 1 and 3 used a conditioned emotional response (CER) procedure and Experiment 2 used two-way active avoidance procedure. Experiments 1 and 2 showed that, in both the CER and avoidance procedures, 1.5 mg/kg dl-amphetamine administered either in the preexposure or the conditioning stage alone did not disrupt LI. In contrast, amphetamine administered in both of the stages abolished LI. Experiment 3 showed that the abolition of LI was obtained when the preexposure and conditioning were given 24 hr apart but not when the two stages were given in one session.

Latent inhibition is not affected by acute or chronic administration of 6 mg/kg dl-amphetamine

Latent inhibition (LI) is a behavioral paradigm in which animals learn to ignore a repeatedly presented stimulus not followed by meaningful consequences. We previously reported that LI was disrupted following the administration of 1.5 mg/kg dl-amphetamine. The present experiments investigated the effects of 6 mg/kg dl-amphetamine administration on LI in a conditioned emotional response (CER) procedure consisting of three stages: pre-exposure, in which the to-be-conditioned stimulus, tone, was repeatedly presented without reinforcement; conditioning, in which the pre-exposed stimulus was paired with shock; and test, where LI was indexed by animals' suppression of licking during tone presentation. The three stages were conducted 24 h apart. In Experiment 1, the drug was administered in a 2 X 2 design, i.e. drug-no drug in pre-exposure and drug-no drug in conditioning. LI was obtained in all conditions. In Experiment 2, animals were given either 5 days of 6 mg/kg amphetamine pretreatment and amphetamine in pre-exposure and conditioning or 7 days of saline. LI was not obtained under amphetamine, but this outcome reflected a state-dependency effect. In Experiment 3, animals received either 5 days of amphetamine pretreatment and amphetamine in pre-exposure, conditioning and test or 8 days of saline. LI was obtained in both the placebo and amphetamine conditions. Experiments 4a and 4b compared the effects of two drug doses, 1.5 (4a) and 6 mg/kg (4b), administered in pre-exposure and conditioning. LI was abolished with the 1.5 mg/kg dose but not with the 6 mg/kg dose.

Alteration of striatal dopaminergic functions implicated in methamphetamine-induced reverse tolerance in rats

Rats were injected repeatedly with methamphetamine (6 mg/kg per day, for 14 days). The effects of the repeated treatment on the change of behaviors and striatal DA metabolism induced by challenge with DA agonists were studied 10 days after the last injection. Repeated methamphetamine administration decreased the sedative effect of low dose apomorphine, and enhanced apomorphine-induced stereotyped behavior but reduced in after pretreatment with tetrabenazine. Striatal DA, HVA and DOPAC contents, and striatal gamma-butyrolactone-induced DA or DOPA accumulation were not altered by repeated methamphetamine treatment. The effect of apomorphine to decrease DA metabolite content and DA or DOPA accumulation was not changed either. As evidenced by experiments using alpha-MT, repeated methamphetamine administration increased DA utilization after methamphetamine or low dose apomorphine challenge, although it did not change DA utilization at the steady state (without drug challenge). These findings suggest that methamphetamine-induced reverse tolerance is accompanied by an increase of DA utilization resulting from the subsensitivity of DA utilization-modulating autoreceptors.

Subchronic methamphetamine treatment selectively attenuates apomorphine-induced decrease in 3,4-dihydroxyphenylacetic acid level in mesolimbic dopaminergic regions

To investigate mechanisms of behavioral enhancement produced by repeated doses of amphetamines, the effects of apomorphine on 3,4-dihydroxyphenylacetic acid (DOPAC) and dopamine (DA) levels were examined in various brain regions of the rat on the 4th day of withdrawal after repeated administration of saline or methamphetamine (3 mg/kg, s.c.) twice daily for 14 days. Apomorphine (0.1 and 1.0 mg/kg, i.p.) produced a dose-dependent decrease in DOPAC levels and no effect on DA levels in the olfactory tubercle, nucleus accumbens, striatum, frontal and cingulate cortices of saline-treated animals. A decrease in DOPAC levels produced by a low dose of apomorphine was attenuated selectively in the olfactory tubercle and nucleus accumbens of methamphetamine-treated animals. A high dose of apomorphine produced a significant decrease in DOPAC levels in both regions. No such attenuation was obtained in the striatum and the frontal and cingulate cortices. These results suggest that subchronic methamphetamine may induce development of hyposensitivity of presynaptic DA receptors in the mesolimbic regions, which contribute to the behavioral enhancement produced by the drug.

Studies on the mechanism of tolerance to methamphetamine

We have reported that the ability of high doses of methamphetamine to impair dopamine and serotonin synthesis in the rat brain is attenuated when animals are pretreated with gradually increasing doses of methamphetamine. To examine the mechanism of this tolerance phenomenon, the effect of methamphetamine on several neurochemical parameters was determined in naive and methamphetamine-pretreated rats. The elevation of nigral substance P concentrations by methamphetamine was attenuated in pretreated compared to naive rats. The methamphetamine-induced reduction in [3H]sulpiride binding in the rat neostriatum and nucleus accumbens was similarly attenuated in animals pretreated with methamphetamine. Determination of brain concentrations of methamphetamine and amphetamine revealed significantly lower concentrations of both compounds in the brains of pretreated compared to naive animals. The results indicate a reduction in the ability of methamphetamine to increase dopamine transmission in the brains of methamphetamine-pretreated rats. Furthermore, this effect appears to be due, at least in part, to a change in the disposition of methamphetamine in pretreated animals.

Specific opioid-amphetamine interactions in the caudate putamen

Bilateral microinjection of morphine (0.003-3 micrograms/side) into the caudate putamen enhances the behavior induced by the IP injection of 1 mg/kg d-amphetamine phosphate in a dose-related manner. The duration of activity was prolonged and ambulation was changed to d-amphetamine stereotypy, a behavior normally associated with higher doses of d-amphetamine. The opioid activity was stereospecific in that levorphanol was active, whereas dextrorphan was not. The enhancement of d-amphetamine-induced behavior by the opioids was blocked by naloxone. D-ala2-met-Enkephalin also enhanced the amphetamine-induced behavior. This enhancement appears to be specific to the caudate putamen because the oral stereotypy observed appears to be a unique action of amphetamine in this region of the brain.

Apomorphine-induced inhibition of neostriatal activity is enhanced by lesions induced by 6-hydroxydopamine but not by long-term administration of amphetamine

Single-unit activity was recorded in the neostriatum of locally-anesthetized, immobilized rats which had received either a unilateral injection of 6-hydroxydopamine (6-OHDA) into the nigro-neostriatal dopamine pathway, or repeated injections (twice daily for 6 days) of saline, 1.0, 5.0 or 10.0 mg/kg (+)-amphetamine. A staircase regimen of apomorphine was administered intravenously to each rat to determine if the long-term administration of amphetamine changed the sensitivity of postsynaptic dopamine receptors in a way comparable to that produced by 6-hydroxydopamine. In all groups, the most frequent response to apomorphine was inhibition of neostriatal activity. In saline-treated rats, most units were moderately excited by small doses of apomorphine (0.0025-0.02 mg/kg) and then inhibited by doses exceeding 0.04 mg/kg. In rats with lesions induced by 6-hydroxydopamine, apomorphine caused significantly more inhibition than in saline-treated animals. By contrast, neuronal responses in amphetamine-treated rats were not significantly different from those of saline controls. These results indicate that the long-term administration of amphetamine produces an augmentation of behavior by some mechanism other than an increase in the sensitivity of postsynaptic dopamine receptors.

Critical issues in assessing the behavioral effects of amphetamine

Amphetamine induces a behavioral syndrome in mammals that includes a variety of repetitive behaviors. An integral component of this syndrome in humans is the presence of a thought disturbance not unlike that manifest in idiopathic paranoid schizophrenia. The consistent pattern of behavioral changes produced by amphetamine across species, when considered in light of the psychosis it elicits in humans, has suggested to many that these drug-induced changes in animals may provide a model of the endogenous psychosis in humans. Amphetamine-induced changes in open-field behavior in the rat have been the most widely studied in attempts to formulate a model for investigating the neurobiological mechanisms underlying amphetamine psychosis and paranoid schizophrenia in humans and for testing the therapeutic efficacy of new antipsychotic drugs. The procedures used to assess the behavioral response to amphetamine, however, typically include rating scales or automated recordings that by their very nature ignore those components of the behavioral response that may be most critical for developing a viable animal model of the naturally occurring psychosis. Further, open-field behavior is often recorded during arbitrarily selected intervals without consideration for the multiphasic nature of the entire amphetamine response. We discuss how incomplete descriptive analyses of the amphetamine behavioral response in rats has led to confusion in the literature and describe behavioral research that is paradigmatic of the work we believe is most likely to eventuate in significant progress in the field.

Effect of continuous systemic infusion of D-amphetamine on the sensitivity of nigral dopamine cells to apomorphine inhibition of firing rates

Using a single-unit recording technique, sensitivity of nigral dopamine neurons to the inhibitory effect of apomorphine was examined on various days after a 7-day pretreatment with osmotic minipumps containing D-amphetamine. Continuous systemic infusion of D-amphetamine produced a short-lasting subsensitivity of nigral neurons to apomorphine (0-2 days after D-amphetamine), followed by a supersensitivity on days 7, 8 and 9, post-amphetamine. The supersensitivity seems to persist at least for one week, suggesting one possible mechanism mediating long-term behavioral and biochemical changes following chronic high-dose amphetamine administration.

Behavioral sensitization and relative hyperresponsiveness of striatal and limbic dopaminergic neurons after repeated methamphetamine treatment

Rats were used in a study of the effects of repeated methamphetamine treatment on stereotyped behavior and striatal and limbic dopamine metabolism in response to challenge with the drug or other dopamine agonists. Repeated administration of d-methamphetamine (6 mg/kg per day for 3-14 days) produced long-term behavioral sensitization (augmented response to a challenge injection) not only to the compound (at 44-89 days after drug withdrawal) but also to apomorphine and nomifensine. Even a single injection of d-methamphetamine (6 mg/kg) enhanced the behavioral response to the drug. A challenge dose of d-methamphetamine (2 mg/kg) markedly increased dopamine turnover (lower dopamine and higher 3,4-dihydroxyphenylacetic acid levels, higher ratios of 3,4-dihydroxyphenylacetic acid over dopamine) in the striatum and mesolimbic area of the sensitized animals on day 15 of withdrawal from treatment repeated for 14 days with the drug (6 mg/kg per day). These findings demonstrate that behavioral sensitization induced by methamphetamine is accompanied by increased central dopaminergic transmission.

Behavioural tolerance to amphetamine and other psychostimulants: the case for considering behavioural mechanisms

An hypothesis is presented about the nature of behavioural tolerance in animals to stimulant drugs. It is suggested that, in many behavioural procedures, tolerance is due to behavioural adaptation to those drug effects which cause disruption of ongoing rewarded behaviour. This unitary hypothesis accounts for the available data on tolerance and cross-tolerance to stimulants more effectively than all of the other more conventional explanations which are based upon dispositional or functional concepts, the most common of which are described, evaluated, and found to be inadequate. Furthermore, it is suggested that attempts to explain tolerance in terms of changes in synaptic functioning are subject to very considerable problems of interpretation and that an analysis of behavioural mechanisms may be of greater value in understanding the process of behavioural tolerance. Evidence for the basic behavioural hypothesis is outlined in some detail, and a theoretical justification presented for its major assumptions. Operant studies of chronic stimulant effects on behaviour have often produced very complex patterns of data, considerable differences being reported both between subjects and between studies. A speculative model is presented which attempts to account for this pattern of data in tolerance studies.

Effects of naloxone on d-amphetamine- and apomorphine-induced behavior

The effects of acute naloxone administration on d-amphetamine- and apomorphine-induced behavior were studied. Naloxone, in doses of 0.3-10 mg/kg (s.c.), antagonized the increase in ambulation and rearing induced by 1 mg/kg of d-amphetamine. When the dose of d-amphetamine was increased to 3 mg/kg, naloxone (3 mg/kg) antagonized only the increase in rearing activity. No dose (0.3-10 mg/kg, s.c.) of naloxone significantly affected d-amphetamine- or apomorphine-induced stereotyped activity. Naloxone (3 mg/kg) significantly augmented the apomorphine (1 mg/kg, s.c.)-induced increase in ambulation but attenuated the apomorphine (0.3 mg/kg)-induced increase in rearing activity. Naloxone (3 mg/kg) or apomorphine (0.03 mg/kg) significantly decreased the ambulation and rearing induced by a novel environment. In combination and in these doses, naloxone and apomorphine produced an additive effect on these behaviors. The neurochemical mechanisms by which naloxone affects d-amphetamine- and apomorphine-induced behavior were investigated. Naloxone (10(-6) M) had no significant effect on [3H]spiroperidol binding in either the caudate nucleus or nucleus accumbens except for a modest inhibition (24%) of both the Km and Bmax in the accumbens microsomal fraction. Similarly, naloxone (10(-6) M) had no significant effect on [3H]dopamine(DA) uptake into either brain region nor did naloxone alter the d-amphetamine-inhibition of uptake. Using perfused tissue slices, naloxone (10(-6)-10(-5) M) significantly attenuated the increase in [3H]DA release induced by d-amphetamine (10(-5) M) in both brain regions. Naloxone (1 mg/kg) had no significant effect on DA or dihydroxyphenyl-acetic acid (DOPAC) levels or on the DA/DOPAC ratio in the caudate nucleus or nucleus accumbens. However, naloxone did reverse the marked increases in the DA-DOPAC ratio induced by d-amphetamine (1 mg/kg) in both brain regions.

Differential sensitivity to amphetamine following long-term treatment with clozapine or haloperidol

When rats were pretreated for 8 consecutive days with 2.0 mg/kg haloperidol, injection of 2.5 or 5.0 mg/kg d-amphetamine 2 or 6 days later resulted in a larger increase in oral behaviors and a more prolonged period of focused sterotypy than in saline-pretreated controls. This increased sensitivity to amphetamine is consistent with the effects of a chronic haloperidol-induced increase in dopamine receptor sensitivity. In contrast, long-term treatment with either d-amphetamine or clozapine produced complex changes in the multiphasic behavioral response to amphetamine, which cannot be explained solely by a shift in the sensitivity of dopamine receptors.

Enhancement of haloperidol-induced increase in rat striatal or mesolimbic 3,4-dihydroxyphenylacetic acid and homovanillic acid by pretreatment with chronic methamphetamine

After a drug-free period of 1 week following 2 weeks of haloperidol treatment, the increased response of striatal 3,4-dihydroxyphenylacetic acid (DOPAC) and homovanillic acid (HVA) to a challenge dose of haloperidol was significantly reduced. Tolerance to this effect was not, however, seen in the mesolimbic system. Pretreatment of the rats with methamphetamine (MAP) for 8 days prior to chronic haloperidol significantly enhanced the DOPAC and HVA increase produced by the challenge with haloperidol in both brain areas. The reduced response of striatal DOPAC or HVA after chronic haloperidol was prevented by pretreatment with MAP. The data suggest that the long-term dopamine receptor stimulation induced by MAP may antagonize the tolerance produced by chronic haloperidol treatment.