Improved prevention and treatment of drug addiction will require deeper understanding of genetic factors contributing to susceptibility to excessive drug use. Intravenous operant self-administration methods have greatly advanced understanding of behavioral traits related to addiction. However, these methods are not suitable for large-scale genetic experiments in mice. Selective breeding of mice can aggregate 'addiction alleles' in a model that has the potential to identify coordinated effects of multiple genes. We produced mouse lines that orally self-administer high (MAHDR) or low (MALDR) amounts of methamphetamine, representing the first demonstration of selective breeding for self-administration of any psychostimulant drug. Conditioned place preference and taste aversion results indicate that MAHDR mice are relatively more sensitive to the rewarding effects and less sensitive to the aversive effects of methamphetamine, compared to MALDR mice. These results validate the oral route of self-administration for investigation of the motivational effects of methamphetamine and provide a viable alternative to intravenous self-administration procedures. Gene expression results for a subset of genes relevant to addiction-related processes suggest differential regulation by methamphetamine of apoptosis and immune pathways in the nucleus accumbens of MAHDR and MALDR mice. In each line, methamphetamine reduced an allostatic state by bringing gene expression back toward 'normal' levels. Genes differentially expressed in the drug-naïve state, including Slc6a4 (serotonin transporter), Htr3a (serotonin receptor 3A), Rela [nuclear factor κB (NFκB)] and Fos (cFos), represent candidates whose expression levels may predict methamphetamine consumption and susceptibility to methamphetamine reward and aversion.
Adenosine A 2A receptors (A 2A Rs) are well positioned to influence the maladaptive CNS responses to repeated dopaminergic stimulation in psychostimulant addiction. Expression of A 2A Rs in brain is largely restricted to the nucleus accumbens and striatum, where molecular adaptations mediate chronic effects of psychostimulants such as behavioral sensitization. Using a novel forebrain-specific conditional (Cre/loxP system) knockout of the A 2A R in coordination with classical pharmacological approaches, we investigated the involvement of brain A 2A Rs in amphetamine-induced behavioral sensitization. Tissue-specific, functional disruption of the receptor was confirmed by autoradiography, PCR, and the loss of A 2A antagonist-induced motor stimulation. Daily treatment with amphetamine for 1 week markedly enhanced locomotor responses on day 8 in control mice and the sensitization remained robust after a week of washout. Their conditional knockout littermates however showed no sensitization to amphetamine on day 8 and only a modest sensitization following the washout. Pharmacological blockade of adenosine A 2A Rs also was able to block the development (but not the expression) of sensitization in multiple mouse strains. Thus activation of brain A 2A Rs plays a critical role in developing augmented psychomotor responses to repeated psychostimulant exposure.
A common expression of neuroadaptations induced by repeated exposure to addictive drugs is a persistent sensitized behavioral response to their stimulant properties. Neuroplasticity underlying drug-induced sensitization has been proposed to explain compulsive drug pursuit and consumption characteristic of addiction. The hypothalamic-pituitary-adrenal (HPA) axis-activating neuropeptide, corticotropin-releasing factor (CRF), may be the keystone in drug-induced neuroadaptation. Corticosterone-activated glucocorticoid receptors (GRs) mediate the development of sensitization to ethanol (EtOH), implicating the HPA axis in this process. EtOHinduced increases in corticosterone require CRF activation of CRF1 receptors. We posited that CRF1 signaling pathways are crucial for EtOH-induced sensitization. We demonstrate that mice lacking CRF1 receptors do not show psychomotor sensitization to EtOH, a phenomenon that was also absent in CRF 1 ؉ 2 receptor doubleknockout mice. Deletion of CRF2 receptors alone did not prevent sensitization. A blunted endocrine response to EtOH was found only in the genotypes showing no sensitization. The CRF1 receptor antagonist CP-154,526 attenuated the acquisition and prevented the expression of EtOH-induced psychomotor sensitization. Because CRF1 receptors are also activated by urocortin-1 (Ucn1), we tested Ucn1 knockout mice for EtOH sensitization and found normal sensitization in this genotype. Finally, we show that the GR antagonist mifepristone does not block the expression of EtOH sensitization. CRF and CRF1 receptors, therefore, are involved in the neurobiological adaptations that underlie the development and expression of psychomotor sensitization to EtOH. A CRF/CRF1-mediated mechanism involving the HPA axis is proposed for acquisition, whereas an extrahypothalamic CRF/CRF1 participation is suggested for expression of sensitization to EtOH.addiction ͉ CP-154,526 ͉ HPA axis ͉ knockout mice ͉ psychomotor sensitization
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