Convergent functional genomic studies of ω-3 fatty acids in stress reactivity, bipolar disorder and alcoholism.

Omega-3 fatty acids have been proposed as an adjuvant treatment option in psychiatric disorders. Given their other health benefits and their relative lack of toxicity, teratogenicity and side effects, they may be particularly useful in children and in females of child-bearing age, especially during pregnancy and postpartum. A comprehensive mechanistic understanding of their effects is needed. Here we report translational studies demonstrating the phenotypic normalization and gene expression effects of dietary omega-3 fatty acids, specifically docosahexaenoic acid (DHA), in a stress-reactive knockout mouse model of bipolar disorder and co-morbid alcoholism, using a bioinformatic convergent functional genomics approach integrating animal model and human data to prioritize disease-relevant genes. Additionally, to validate at a behavioral level the novel observed effects on decreasing alcohol consumption, we also tested the effects of DHA in an independent animal model, alcohol-preferring (P) rats, a well-established animal model of alcoholism. Our studies uncover sex differences, brain region-specific effects and blood biomarkers that may underpin the effects of DHA. Of note, DHA modulates some of the same genes targeted by current psychotropic medications, as well as increases myelin-related gene expression. Myelin-related gene expression decrease is a common, if nonspecific, denominator of neuropsychiatric disorders. In conclusion, our work supports the potential utility of omega-3 fatty acids, specifically DHA, for a spectrum of psychiatric disorders such as stress disorders, bipolar disorder, alcoholism and beyond.

Convergent functional genomics of anxiety disorders: translational identification of genes, biomarkers, pathways and mechanisms.

Anxiety disorders are prevalent and disabling yet understudied from a genetic standpoint, compared with other major psychiatric disorders such as bipolar disorder and schizophrenia. The fact that they are more common, diverse and perceived as embedded in normal life may explain this relative oversight. In addition, as for other psychiatric disorders, there are technical challenges related to the identification and validation of candidate genes and peripheral biomarkers. Human studies, particularly genetic ones, are susceptible to the issue of being underpowered, because of genetic heterogeneity, the effect of variable environmental exposure on gene expression, and difficulty of accrual of large, well phenotyped cohorts. Animal model gene expression studies, in a genetically homogeneous and experimentally tractable setting, can avoid artifacts and provide sensitivity of detection. Subsequent translational integration of the animal model datasets with human genetic and gene expression datasets can ensure cross-validatory power and specificity for illness. We have used a pharmacogenomic mouse model (involving treatments with an anxiogenic drug--yohimbine, and an anti-anxiety drug--diazepam) as a discovery engine for identification of anxiety candidate genes as well as potential blood biomarkers. Gene expression changes in key brain regions for anxiety (prefrontal cortex, amygdala and hippocampus) and blood were analyzed using a convergent functional genomics (CFG) approach, which integrates our new data with published human and animal model data, as a translational strategy of cross-matching and prioritizing findings. Our work identifies top candidate genes (such as FOS, GABBR1, NR4A2, DRD1, ADORA2A, QKI, RGS2, PTGDS, HSPA1B, DYNLL2, CCKBR and DBP), brain-blood biomarkers (such as FOS, QKI and HSPA1B), pathways (such as cAMP signaling) and mechanisms for anxiety disorders--notably signal transduction and reactivity to environment, with a prominent role for the hippocampus. Overall, this work complements our previous similar work (on bipolar mood disorders and schizophrenia) conducted over the last decade. It concludes our programmatic first pass mapping of the genomic landscape of the triad of major psychiatric disorder domains using CFG, and permitted us to uncover the significant genetic overlap between anxiety and these other major psychiatric disorders, notably the under-appreciated overlap with schizophrenia. PDE10A, TAC1 and other genes uncovered by our work provide a molecular basis for the frequently observed clinical co-morbidity and interdependence between anxiety and other major psychiatric disorders, and suggest schizo-anxiety as a possible new nosological domain.

Convergent functional genomics of genome-wide association data for bipolar disorder: comprehensive identification of candidate genes, pathways and mechanisms.

Given the mounting convergent evidence implicating many more genes in complex disorders such as bipolar disorder than the small number identified unambiguously by the first-generation Genome-Wide Association studies (GWAS) to date, there is a strong need for improvements in methodology. One strategy is to include in the next generation GWAS larger numbers of subjects, and/or to pool independent studies into meta-analyses. We propose and provide proof of principle for the use of a complementary approach, convergent functional genomics (CFG), as a way of mining the existing GWAS datasets for signals that are there already, but did not reach significance using a genetics-only approach. With the CFG approach, the integration of genetics with genomics, of human and animal model data, and of multiple independent lines of evidence converging on the same genes offers a way of extracting signal from noise and prioritizing candidates. In essence our analysis is the most comprehensive integration of genetics and functional genomics to date in the field of bipolar disorder, yielding a series of novel (such as Klf12, Aldh1a1, A2bp1, Ak3l1, Rorb, Rora) and previously known (such as Bdnf, Arntl, Gsk3b, Disc1, Nrg1, Htr2a) candidate genes, blood biomarkers, as well as a comprehensive identification of pathways and mechanisms. These become prime targets for hypothesis driven follow-up studies, new drug development and personalized medicine approaches.

Potential adverse effects of amphetamine treatment on brain and behavior: a review.

Amphetamine stimulants have been used medically since early in the twentieth century, but they have a high abuse potential and can be neurotoxic. Although they have long been used effectively to treat attention deficit hyperactivity disorder (ADHD) in children and adolescents, amphetamines are now being prescribed increasingly as maintenance therapy for ADHD and narcolepsy in adults, considerably extending the period of potential exposure. Effects of prolonged stimulant treatment have not been fully explored, and understanding such effects is a research priority. Because the pharmacokinetics of amphetamines differ between children and adults, reevaluation of the potential for adverse effects of chronic treatment of adults is essential. Despite information on the effects of stimulants in laboratory animals, profound species differences in susceptibility to stimulant-induced neurotoxicity underscore the need for systematic studies of prolonged human exposure. Early amphetamine treatment has been linked to slowing in height and weight growth in some children. Because the number of prescriptions for amphetamines has increased several fold over the past decade, an amphetamine-containing formulation is the most commonly prescribed stimulant in North America, and it is noteworthy that amphetamines are also the most abused prescription medications. Although early treatment does not increase risk for substance abuse, few studies have tracked the compliance and usage profiles of individuals who began amphetamine treatment as adults. Overall, there is concern about risk for slowed growth in young patients who are dosed continuously, and for substance abuse in patients first medicated in late adolescence or adulthood. Although most adult patients also use amphetamines effectively and safely, occasional case reports indicate that prescription use can produce marked psychological adverse events, including stimulant-induced psychosis. Assessments of central toxicity and adverse psychological effects during late adulthood and senescence of adults who receive prolonged courses of amphetamine treatment are warranted. Finally, identification of the biological factors that confer risk and those that offer protection is also needed to better specify the parameters of safe, long-term, therapeutic administration of amphetamines to adults.

Phenomic, convergent functional genomic, and biomarker studies in a stress-reactive genetic animal model of bipolar disorder and co-morbid alcoholism.

We had previously identified the clock gene D-box binding protein (Dbp) as a potential candidate gene for bipolar disorder and for alcoholism, using a Convergent Functional Genomics (CFG) approach. Here we report that mice with a homozygous deletion of DBP have lower locomotor activity, blunted responses to stimulants, and gain less weight over time. In response to a chronic stress paradigm, these mice exhibit a diametric switch in these phenotypes. DBP knockout mice are also activated by sleep deprivation, similar to bipolar patients, and that activation is prevented by treatment with the mood stabilizer drug valproate. Moreover, these mice show increased alcohol intake following exposure to stress. Microarray studies of brain and blood reveal a pattern of gene expression changes that may explain the observed phenotypes. CFG analysis of the gene expression changes identified a series of novel candidate genes and blood biomarkers for bipolar disorder, alcoholism, and stress reactivity.

Convergent Functional Genomics of bipolar disorder: from animal model pharmacogenomics to human genetics and biomarkers.

Progress in understanding the genetic and neurobiological basis of bipolar disorder(s) has come from both human studies and animal model studies. Until recently, the lack of concerted integration between the two approaches has been hindering the pace of discovery, or more exactly, constituted a missed opportunity to accelerate our understanding of this complex and heterogeneous group of disorders. Our group has helped overcome this "lost in translation" barrier by developing an approach called convergent functional genomics (CFG). The approach integrates animal model gene expression data with human genetic linkage/association data, as well as human tissue (postmortem brain, blood) data. This Bayesian strategy for cross-validating findings extracts meaning from large datasets, and prioritizes candidate genes, pathways and mechanisms for subsequent targeted, hypothesis-driven research. The CFG approach may also be particularly useful for identification of blood biomarkers of the illness.

Towards understanding the schizophrenia code: an expanded convergent functional genomics approach.

Identifying genes for schizophrenia through classical genetic approaches has proven arduous. Here, we present a comprehensive convergent analysis that translationally integrates brain gene expression data from a relevant pharmacogenomic mouse model (involving treatments with a psychomimetic agent - phencyclidine (PCP), and an anti-psychotic - clozapine), with human genetic linkage data and human postmortem brain data, as a Bayesian strategy of cross validating findings. Topping the list of candidate genes, we have three genes involved in GABA neurotransmission (GABRA1, GABBR1, and GAD2), one gene involved in glutamate neurotransmission (GRIA2), one gene involved in neuropeptide signaling (TAC1), two genes involved in synaptic function (SYN2 and KCNJ4), six genes involved in myelin/glial function (CNP, MAL, MBP, PLP1, MOBP and GFAP), and one gene involved in lipid metabolism (LPL). These data suggest that schizophrenia is primarily a disorder of brain functional and structural connectivity, with GABA neurotransmission playing a prominent role. These findings may explain the EEG gamma band abnormalities detected in schizophrenia. The analysis also revealed other high probability candidates genes (neurotransmitter signaling, other structural proteins, ion channels, signal transduction, regulatory enzymes, neuronal migration/neurite outgrowth, clock genes, transcription factors, RNA regulatory genes), pathways and mechanisms of likely importance in pathophysiology. Some of the pathways identified suggest possible avenues for augmentation pharmacotherapy of schizophrenia with other existing agents, such as benzodiazepines, anticonvulsants and lipid modulating agents. Other pathways are new potential targets for drug development. Lastly, a comparison with our earlier work on bipolar disorder illuminates the significant molecular overlap between schizophrenia and bipolar disorder.

Convergent functional genomics: a Bayesian candidate gene identification approach for complex disorders.

Identifying genes involved in complex neuropsychiatric disorders through classic human genetic approaches has proven difficult. To overcome that barrier, we have developed a translational approach called Convergent Functional Genomics (CFG), which cross-matches animal model microarray gene expression data with human genetic linkage data as well as human postmortem brain data and biological role data, as a Bayesian way of cross-validating findings and reducing uncertainty. Our approach produces a short list of high probability candidate genes out of the hundreds of genes changed in microarray datasets and the hundreds of genes present in a linkage peak chromosomal area. These genes can then be prioritized, pursued, and validated in an individual fashion using: (1) human candidate gene association studies and (2) cell culture and mouse transgenic models. Further bioinformatics analysis of groups of genes identified through CFG leads to insights into pathways and mechanisms that may be involved in the pathophysiology of the illness studied. This simple but powerful approach is likely generalizable to other complex, non-neuropsychiatric disorders, for which good animal models, as well as good human genetic linkage datasets and human target tissue gene expression datasets exist.

Candidate genes, pathways and mechanisms for bipolar (manic-depressive) and related disorders: an expanded convergent functional genomics approach.

Identifying genes for bipolar mood disorders through classic genetics has proven difficult. Here, we present a comprehensive convergent approach that translationally integrates brain gene expression data from a relevant pharmacogenomic mouse model (involving treatments with a stimulant--methamphetamine, and a mood stabilizer--valproate), with human data (linkage loci from human genetic studies, changes in postmortem brains from patients), as a bayesian strategy of crossvalidating findings. Topping the list of candidate genes, we have DARPP-32 (dopamine- and cAMP-regulated phosphoprotein of 32 kDa) located at 17q12, PENK (preproenkephalin) located at 8q12.1, and TAC1 (tachykinin 1, substance P) located at 7q21.3. These data suggest that more primitive molecular mechanisms involved in pleasure and pain may have been recruited by evolution to play a role in higher mental functions such as mood. The analysis also revealed other high-probability candidates genes (neurogenesis, neurotrophic, neurotransmitter, signal transduction, circadian, synaptic, and myelin related), pathways and mechanisms of likely importance in pathophysiology.

Caudate-putamen and nucleus accumbens extracellular acetylcholine responses to methamphetamine binges.

Exposure of experimental animals to an escalating dose, multiple binge pattern of methamphetamine administration results in the progressive emergence of a unique behavioral profile, which includes a significant decrease in the duration of the stereotypy phase as well as a profound increase and qualitative change in the locomotor activation. This behavioral profile is associated with a selective decrease in the caudate-putamen but not nucleus accumbens extracellular dopamine response. Since the acetylcholine interneurons in these regions are partly under the control of the mesostriatal and mesoaccumbens dopamine inputs, changes in the activation of these interneurons should parallel the regionally differential dopamine responses during multiple binge treatment. Therefore, we characterized the caudate-putamen and nucleus accumbens extracellular acetylcholine responses to escalating-dose, multiple binge methamphetamine administration. An acute methamphetamine binge decreased acetylcholine levels in caudate-putamen, but had no effect on levels in nucleus accumbens. Furthermore, corresponding to the selective decrease in the dopamine response, the caudate-putamen but not nucleus accumbens extracellular acetylcholine response exhibited tolerance with repeated binge exposures; i.e. the decrease in acetylcholine associated with the acute methamphetamine binge was attenuated with multiple binge exposure. These results are consistent with our hypothesis and suggest that the regionally differential acetylcholine responses reflect one functional consequence of the escalating-dose, multiple binge stimulant treatment.

Relevance of pharmacokinetic parameters in animal models of methamphetamine abuse.

Although the behavioral consequences of methamphetamine (METH) abuse have been extensively documented, a more precise and thorough understanding of underlying neurobiological mechanisms still requires the use of animal models. To study these biochemical processes in experimental animals requires consideration for the broad range of human METH abuse patterns and the many factors that have been identified to profoundly influence the behavioral and neurochemical effects of exposure to METH-like stimulants. One potentially critical issue relates to pharmacokinetic differences between the species. In this review, METH plasma pharmacokinetic profiles after single and multiple dose intravenous METH administration are compared for the rat and human. Significant differences in elimination half-life between the two species (t1/2: rat-70 min, human-12 h) result in markedly dissimilar profiles of METH exposure. However, the plasma profile of a human METH binge pattern can be approximated in the rat by increasing METH dose frequency. Consideration of METH pharmacokinetics in animal models should permit a closer simulation of the temporal profile of METH exposure in the human CNS and should provide further insight into the mechanisms contributing to the addiciton and psychopathology associated with METH abuse.

Locomotor effects of acute and repeated threshold doses of amphetamine and methylphenidate: relative roles of dopamine and norepinephrine.

The prescribed use of methylphenidate (Ritalin) in the treatment of attention deficit hyperactivity disorder has risen dramatically in recent years. The relative roles of dopamine, norepinephrine, and serotonin in the therapeutic action of these drugs was assessed by comparing the responses of extracellular nucleus accumbens dopamine and serotonin and hippocampus norepinephrine to the acute administration of low methylphenidate and amphetamine doses. The comparative neurochemical profiles in response to methylphenidate and amphetamine suggest that the norepinephrine effects may play an important role in the therapeutic effects of low doses of psychostimulants. In addition, to assess possible long-term consequences of prolonged exposure to this drug, we examined whether changes in the locomotor response occurred with repeated administration of these stimulant doses. Threshold doses of methylphenidate (0.5-1.0 mg/kg) or amphetamine (0.1-0.25 mg/kg) were administered twice daily, and then animals were tested in response to 2.5 mg/kg methylphenidate or 0.5 mg/kg amphetamine. Our results provide evidence that low-dose stimulant administration can result in the development of behavioral sensitization, which is evident in the subsequent behavioral response to the drug. The relevance of these data to the therapeutic uses of these drugs is discussed within the context of the many variables that can affect the behavioral and neurochemical responses to stimulants.

Identifying a series of candidate genes for mania and psychosis: a convergent functional genomics approach.

We have used methamphetamine treatment of rats as an animal model for psychotic mania. Specific brain regions were analyzed comprehensively for changes in gene expression using oligonucleotide GeneChip microarrays. The data was cross-matched against human genomic loci associated with either bipolar disorder or schizophrenia. Using this convergent approach, we have identified several novel candidate genes (e.g., signal transduction molecules, transcription factors, metabolic enzymes) that may be involved in the pathogenesis of mood disorders and psychosis. Furthermore, for one of these genes, G protein-coupled receptor kinase 3 (GRK3), we found by Western blot analysis evidence for decreased protein levels in a subset of patient lymphoblastoid cell lines that correlated with disease severity. Finally, the classification of these candidate genes into two prototypical categories, psychogenes and psychosis-suppressor genes, is described.

In vivo microdialysis assessment of extracellular serotonin and dopamine levels in awake monkeys during sustained fluoxetine administration.

Fluoxetine (FLU) rapidly enhances extracellular (EC) serotonin (5-HT) in rodent brain, whereas the antidepressant effects of this drug in humans are typically not observed for 2-3 weeks. Thus, the effects of chronic oral FLU administration on neocortical and hippocampal EC 5-HT, and on caudate EC 5-HT and dopamine (DA), were examined in awake monkeys (Macaca fascicularis) using in vivo microdialysis (10.0 mg/kg; 3, 7, 14, and 21 days). On day 3, 5-HT was significantly increased above baseline levels in hippocampus (HC) and caudate. There was a trend for an increase in neocortex EC 5-HT levels. However, by day 7 5-HT remained significantly elevated only in HC, although 5-HT levels elsewhere had not completely returned to baseline. In contrast, levels of the 5-HT metabolite, 5-HIAA, were significantly reduced in all brain regions at all time points. Caudate DA levels tended to be decreased throughout FLU treatment. Local FLU and K(+) infusion were also used at various times during chronic systemic FLU administration to evaluate changes in functional synaptic regulation. In general, these results, along with the significant decrease in 5-HIAA levels and the tendency for basal EC 5-HT levels to remain modestly elevated only in HC during sustained FLU administration, suggest a reduction in releasable pools of 5-HT. Taken together with the trend for a decrease in caudate EC DA levels, these results do not appear to support the current hypothesis regarding the mechanism of action of SSRI antidepressants-that monoaminergic neurotransmission is progressively augmented during chronic treatment.

Differential regional zif268 messenger RNA expression in an escalating dose/binge model of amphetamine-induced psychosis.

Amphetamine-induced psychosis is most often associated with a high-dose multiple binge pattern of stimulant abuse. To simulate these conditions in rats, we used an escalating dose/binge administration paradigm. Animals were pretreated with escalating doses of amphetamine (1.0-8.0mg/kg) over four days, then exposed to nine daily binges (8.0mg/kg every 2h; four injections/day). Other animals received either multiple injections of saline, saline followed by acute amphetamine (8.0mg/kg) or single daily injections of amphetamine (8.0mg/kg) in parallel with the escalating dose/binge treatment. One hour after the last injection, all animals were decapitated and regional brain activation patterns were assessed using in situ hybridization with antisense probes for zif268. Acute amphetamine resulted in a significant elevation of zif268 messenger RNA in both the nucleus accumbens and dorsal striatum. However, whereas after single daily amphetamine treatment this index was no longer elevated above control levels in the dorsal striatum, multiple binge exposures were required for the nucleus accumbens to return to baseline. Agranular insular cortex and medial olfactory tubercle zif268 messenger RNA expression was also markedly increased after acute amphetamine treatment but, unlike the nucleus accumbens and dorsal striatum, this increase was not significantly attenuated by either single daily injection or multiple binge treatment. Zif268 messenger RNA expression in the lateral nucleus of the amygdala also remained elevated above baseline after binge treatment. The possible relationships of these changes in zif268 messenger RNA regional expression patterns to the development of psychosis in high-dose stimulant abusers are discussed.

Dynamic changes in sensitivity occur during the acute response to cocaine and methylphenidate.

RATIONALE: We have previously shown that during the acute response to amphetamine, a stimulant that released dopamine, behavioral sensitivity to the drug undergoes dynamic changes, as evident in the altered behavioral profile expressed to the subsequent administration of a low dose of the drug. OBJECTIVE: The present studies were designed to determine if these dynamic changes in sensitivity occur with amphetamine-like stimulants that act primarily by blocking dopamine uptake. METHODS: Groups of animals were primed with 40 mg/kg cocaine or 30 mg/kg methylphenidate, then during the acute response, a low, locomotor-stimulant dose of amphetamine (1.5 mg/kg) was administered to probe for changes in sensitivity. Conversely, to determine whether the manifestation of the increased responsivity is idiosyncratic to amphetamine, animals were also primed with amphetamine (4 mg/kg), then probed with low doses of cocaine (10 and 20 mg/kg) or methylphenidate (10 mg/kg). Parallel microdialysis studies were performed to assess the caudate-put-amen and nucleus accumbens extracellular dopamine responses. RESULTS: Priming with the uptake blockers each resulted in a stereotypy response to the subsequent low-dose amphetamine probe. Likewise, after priming with amphetamine, the uptake blockers each induced a pronounced stereotypy response. In each case, these changes in behavioral responsivity were expressed in the absence of corresponding changes in the probe-induced regional dopamine responses. CONCLUSIONS: Dynamic changes in behavioral sensitivity during the response to acute stimulant administration are a characteristic common to both dopamine releasers and uptake blockers. These rapid changes in sensitivity may contribute to the behaviors associated with binge patterns of drug abuse.

Escalating dose-binge treatment with methylphenidate: role of serotonin in the emergent behavioral profile.

Our previous studies indicate that exposure of rats to an escalating-dose, multibinge pattern of amphetamine or methamphetamine administration results in a unique emergent behavioral profile and concomitant regionally specific dopamine response patterns in the nucleus accumbens and caudate-putamen. In the present study, we explored the generality of these effects by using an escalating-dose, multibinge treatment with methylphenidate (MP), a stimulant that, unlike the amphetamines, produces no increase in serotonin transmission. Furthermore, MP exerts many of its effects through dopamine uptake blockade, in contrast to the amphetamines that primarily release dopamine. The results showed that MP administered according to an escalating-dose, multibinge regimen produced the expression of the emergent behavioral profile. This pattern of behavior was also evident in these animals in response to 2.5 mg/kg acute amphetamine after the last MP binge exposure. Consistent with previous evidence, neither acute nor multibinge MP treatment produced a significant serotonin response. In contrast, a regionally specific dopamine response alteration was observed during the course of this treatment. Caudate-putamen dopamine exhibited a pattern of increasing response during an acute MP binge but pronounced tolerance developed to this effect after multiple binges. By contrast, the nucleus accumbens dopamine response did not significantly change during the acute binge and exhibited a slight incremental pattern to the injections of the final binge. These findings, along with the effects of other stimulants, are discussed in terms of a possible role for serotonin and for the differential changes in the caudate-putamen and nucleus accumbens dopamine responses in the emergent behavioral profile. The similarity between the effects of MP and the amphetamines provides further support for the multibinge-induced behavioral profile as a possible animal model for stimulant-induced psychosis.

Escalating dose-binge stimulant exposure: relationship between emergent behavioral profile and differential caudate-putamen and nucleus accumbens dopamine responses.

Previous studies showed that treatment with high doses of amphetamine (8.0 mg/kg) administered according to an escalating dose-binge regimen, produced a unique behavioral profile that included a decrease in the duration of stereotypy and a pronounced increase in ambulation, characterized by a repeated bursting pattern of locomotion. This treatment regimen also resulted in differential dopamine response profiles in the caudate-putamen and nucleus accumbens: the dopamine response in the caudate-putamen exhibited a progressive within and between binge decline in peak levels, whereas the dopamine response in the nucleus accumbens was not significantly altered. The present study was designed to determine if this behavioral/dopamine response relationship was obtained under two additional conditions: first, in response to a relatively low dose amphetamine challenge (2.5 mg/kg) after withdrawal from escalating dose-binge treatment with either amphetamine or methamphetamine (6.0 mg/kg), and, second, during a lower dose (2.5 mg/kg amphetamine) escalating dose-binge regimen. Both the emergent behavioral profile and the regional differences in the dopamine response patterns were obtained under each set of conditions. These effects may be significantly implicated in the induction of stimulant psychosis, since the psychotogenic effects of amphetamine-like stimulants are most commonly associated with frequent, relatively high dose binge exposures.

Sensitization of amphetamine-induced stereotyped behaviors during the acute response: role of D1 and D2 dopamine receptors.

During the response to an injection of amphetamine, rapid changes occur in the ability of the drug to induce stereotyped behaviors. This enhanced responsivity does not involve changes in the caudate-putamen or nucleus accumbens extracellular dopamine response, but appears to require activation of dopamine receptors. In the present studies we examined the role that D1 and D2 dopamine receptors might play in the development and expression of the enhanced stereotypy response. In one series of experiments we used the dopamine agonists, SKF 82958 and quinpirole as relatively selective probes at D1 and D2 dopamine receptors, respectively, to test for changes in dopamine receptor sensitivity following a pretreatment ('priming') with 4.0 mg/kg amphetamine. Doses of both SKF 82958 and quinpirole which were sub-threshold to induce perseverative behaviors in control animals, promoted stereotyped behaviors in amphetamine-primed animals, suggesting an enhanced sensitivity of both D1 and D2 receptors. In a second series of experiments, we sought to determine whether priming with these relatively selective dopamine receptor agonists, as well as the mixed D1/D2 agonist, apomorphine, would result in an enhanced stereotypy response to the subsequent administration of non-stereotypy producing doses of amphetamine (0.5-1.5 mg/kg). Priming with the dopamine receptor agonists each resulted in an enhanced amphetamine-induced stereotypy response. These results indicate that both D1 and D2 dopamine receptors contribute to both the development and the expression of the altered stereotypy responsivity, though several dose- and time-related observations suggest that other mechanisms likely contribute as well. Because these changes are apparent during the amphetamine response, they may have important implications for the evolving behavioral alterations which result when stimulants are administered in a binge pattern of drug abuse.

Caudate-putamen dopamine and stereotypy response profiles after intravenous and subcutaneous amphetamine.

We compared the behavioral and caudate-putamen extracellular dopamine responses following intravenous (3.6 mg/kg) and subcutaneous (8 mg/kg) amphetamine administration using 2-min microdialysate sampling intervals, and doses of the drug selected to achieve comparable maximal brain concentrations. Following intravenous amphetamine, dopamine peaked within the first 2 min, then declined with a first-order decay rate of 0.018+/-0.007 min(-1). Following subcutaneous amphetamine, dopamine achieved maximum concentrations at 9 min and remained near peak levels for about 30 min before declining with a first-order decay rate of 0.019+/-0.008 min(-1). Maximal brain amphetamine levels and peak dopamine concentrations were equivalent following either route of drug administration. In contrast to the short latency to maximal extracellular dopamine, the onset of oral stereotypies was delayed until about 30 min following both routes of drug administration. Furthermore, in contrast to the behavioral response to amphetamine, apomorphine administration resulted in the rapid appearance of oral stereotypies within 5-10 min after drug administration. These results suggest that although caudate-putamen dopamine receptor activation may be a critical factor in the expression of focused oral stereotypies, other effects of amphetamine may interfere with the ability of animals to exhibit these behaviors.