Permanent impairment of birth and survival of cortical and hippocampal proliferating cells following excessive drinking during alcohol dependence.

Experimenter-delivered alcohol decreases adult hippocampal neurogenesis and hippocampal-dependent learning and memory. The present study used clinically relevant rodent models of nondependent limited access alcohol self-administration and excessive drinking during alcohol dependence (alcohol self-administration followed by intermittent exposure to alcohol vapors over several weeks) to compare alcohol-induced effects on cortical gliogenesis and hippocampal neurogenesis. Alcohol dependence, but not nondependent drinking, reduced proliferation and survival in the medial prefrontal cortex (mPFC). Apoptosis was reduced in both alcohol groups within the mPFC, which may reflect an initiation of a reparative environment following alcohol exposure as decreased proliferation was abolished after prolonged dependence. Reduced proliferation, differentiation, and neurogenesis were observed in the hippocampus of both alcohol groups, and prolonged dependence worsened the effects. Increased hippocampal apoptosis and neuronal degeneration following alcohol exposure suggest a loss in neuronal turnover and indicate that the hippocampal neurogenic niche is highly vulnerable to alcohol.

Corticotropin-releasing factor-1 receptor antagonists decrease heroin self-administration in long- but not short-access rats.

Dysregulation of the stress-related corticotropin-releasing factor (CRF) system has been implicated in the development of drug dependence. The present study examined the effects of administering CRF type 1 (CRF(1)) receptor antagonists on heroin self-administration in animals allowed short (1 hour) or long (8-12 hours) access to intravenous heroin self-administration sessions. The nonpeptide CRF(1) antagonists MJL-1-109-2 (1 hour versus 8 hours access) or R121919 (1 hour versus 12 hours access) were systemically injected in both short- and long-access rats. MJL-1-109-2 (10 mg/kg) and R121919 (10 and 20 mg/kg) reduced heroin self-administration in long-access animals without altering heroin intake in short-access animals. Both MJL-1-109-2 and R121919 decreased first-hour intravenous heroin self-administration selectively in long-access rats, with R121919 decreasing cumulative heroin intake across the 12-hour session. The results demonstrate that blockade of the CRF-CRF(1) receptor system attenuates the increased heroin intake of rats with extended access to the drug.

MPZP: a novel small molecule corticotropin-releasing factor type 1 receptor (CRF1) antagonist.

The extrahypothalamic stress peptide corticotropin-releasing factor (CRF) system is an important regulator of behavioral responses to stress. Dysregulation of CRF and the CRF type 1 receptor (CRF(1)) system is hypothesized to underlie many stress-related disorders. Modulation of the CRF(1) system by non-peptide antagonists currently is being explored as a therapeutic approach for anxiety disorders and alcohol dependence. Here, we describe a new, less hydrophilic (cLogP approximately 2.95), small molecule, non-peptide CRF(1) antagonist with high affinity (K(i)=4.9 nM) and specificity for CRF(1) receptors: N,N-bis(2-methoxyethyl)-3-(4-methoxy-2-methylphenyl)-2,5-dimethyl-pyrazolo[1,5-a] pyrimidin-7-amine (MPZP). The compound was systemically administered to adult male rats in two behavioral models dependent on the CRF(1) system: defensive burying (0, 5, 20 mg/kg, n=6-11 for each dose) and alcohol dependence (0, 5, 10, 20 mg/kg, n=8 for each self-administration group). Acute administration of MPZP reduced burying behavior in the defensive burying model of active anxiety-like behavior. MPZP also attenuated withdrawal-induced excessive drinking in the self-administration model of alcohol dependence without affecting nondependent alcohol drinking or water consumption. The present findings support the proposed significance of the CRF(1) system in anxiety and alcohol dependence and introduce a promising new compound for further development in the treatment of alcohol dependence and stress-related disorders.

Corticotropin-releasing factor within the central nucleus of the amygdala mediates enhanced ethanol self-administration in withdrawn, ethanol-dependent rats.

Alcohol dependence is characterized by excessive consumption, loss of control over intake, and the presence of a withdrawal syndrome, including both motivational and physical symptoms. The motivational symptoms, including anxiety, have been hypothesized to be important factors eliciting excessive drinking during abstinence. Previous work has shown that ethanol-dependent rats also display enhanced anxiety-like behaviors and enhanced ethanol self-administration during withdrawal, likely resulting from dysregulation of brain corticotropin-releasing factor (CRF) stress systems. The present study was designed to explore the brain sites within the extended amygdala [central nucleus of the amygdala (CeA), lateral bed nucleus of the stria terminalis (BNST), and nucleus accumbens shell (NAcSh)] that mediate the increased ethanol self-administration observed during withdrawal. Ethanol-dependent animals showed an increase in ethanol self-administration after acute withdrawal relative to nondependent controls. The CRF antagonist D-Phe-CRF(12-41) ([D-Phe(12),Nle(21,38),C alpha MeLeu(37)]-rCRF(12-41)) was administered into the CeA, lateral BNST, or NAcSh of acute-withdrawn dependent and nondependent rats. Administered into the CeA, the antagonist reduced ethanol self-administration in dependent animals, with no effect in nondependent animals. Administration of D-Phe-CRF(12-41) into the lateral BNST and NAcSh was without effect on ethanol self-administration in dependent and nondependent animals. At the same time point of withdrawal, there was a decrease in CRF immunoreactivity within the CeA, suggesting an increased extracellular release of CRF during withdrawal. There was no change in CRF immunoreactivity in the BNST or NAcSh. These results indicate that CRF, specifically within the CeA, plays a role in mediating excessive ethanol consumption in ethanol-dependent animals.

Corticotropin-releasing factor 1 antagonists selectively reduce ethanol self-administration in ethanol-dependent rats.

BACKGROUND: Alcohol dependence is characterized by excessive alcohol consumption, loss of control over intake, and the presence of a withdrawal syndrome, which includes both motivational and physical symptoms. Similar to human alcoholics, ethanol-dependent animals display enhanced anxiety-like behaviors and enhanced ethanol self-administration during withdrawal, effects hypothesized to result from a dysregulation of corticotropin-releasing factor (CRF) stress systems. Here, we used an animal model of ethanol dependence to test the effects of CRF(1) receptor antagonists on excessive ethanol self-administration in dependent rats. METHODS: Wistar rats, trained to orally self-administer ethanol, were exposed intermittently to ethanol vapors to induce ethanol dependence. Nondependent animals were exposed to control air. Following a 2-hour period of withdrawal, dependent and nondependent animals were systemically administered antalarmin, MJL-1-109-2, or R121919 (CRF(1) antagonists) and ethanol self-administration was measured. RESULTS: The nonpeptide, small molecule CRF(1) antagonists selectively reduced excessive self-administration of ethanol in dependent animals during acute withdrawal. The antagonists had no effect on ethanol self-administration in nondependent rats. CONCLUSIONS: These data demonstrate that CRF(1) receptors play an important role in mediating excessive ethanol self-administration in dependent rats, with no effect in nondependent rats. CRF(1) antagonists may be exciting new pharmacotherapeutic targets for the treatment of alcoholism in humans.

Chronic ethanol exposure inhibits dopamine release via effects on the presynaptic actin cytoskeleton in PC12 cells.

An increase in nucleus accumbens dopamine release appears to mediate the "rewarding" properties of drugs of abuse. Using PC12 cells, it has been shown that chronic ethanol exposure can significantly reduce nicotine-stimulated dopamine release. Here, a novel mechanism of ethanol in regulating presynaptic dopamine release is demonstrated. In neuronal cells, a layer of filamentous actin beneath the cell surface regulates the movement and release of synaptic vesicles. Upon stimulation, there is a protein kinase C (PKC)-dependent breakdown of this actin cytoskeleton, allowing vesicles to move near the nerve terminal membrane for release. Chronic ethanol alters PKC signaling, thus the hypothesis that chronic ethanol inhibits presynaptic actin cytoskeleton breakdown in response to stimulation was tested. PC12 cells were chronically exposed to ethanol and then acutely exposed to multiple forms of stimulation (nicotine, sucrose, potassium, and ionophore). In ethanol-treated cells, dopamine release was inhibited following stimulation by forms of release shown to be PKC-dependent (nicotine, sucrose, and potassium). In contrast, dopamine release was not altered following stimulation by PKC-independent forms of release (ionophore). Actin cytoskeleton breakdown was also inhibited following stimulation with PKC-dependent forms of stimulated release but not by PKC-independent (ionophore) forms. Further, cytochalasin B, an agent which depolymerizes actin, reversed the effects of chronic ethanol on both actin depolymerization and dopamine release. These data suggest that chronic ethanol inhibits presynaptic actin breakdown, likely resulting in decreased neurotransmitter release.

A CRF(2) agonist administered into the central nucleus of the amygdala decreases ethanol self-administration in ethanol-dependent rats.

Alcohol dependence is characterized by excessive consumption, loss of control over intake and the presence of a withdrawal syndrome, including both motivational and physical symptoms. Previous studies have implicated the brain corticotropin-releasing factor (CRF) stress systems in mediating the negative emotional state associated with ethanol withdrawal. CRF(1) receptor-specific antagonists, administered systemically, and CRF receptor subtype nonspecific antagonists, administered into the central nucleus of the amygdala (CeA), selectively decrease the anxiety-like behaviors and increased ethanol self-administration associated with ethanol withdrawal. In the present study, we investigated the role of CRF(2) receptors within the CeA in mediating ethanol self-administration in ethanol-dependent and nondependent animals. Male Wistar rats were made dependent on ethanol using an intermittent ethanol vapor exposure paradigm. Nondependent animals received similar conditions but were exposed to air only. Following 2 h of withdrawal from ethanol vapors, ethanol and water self-administration were measured following administration of urocortin 3, a highly selective CRF(2) agonist, in the CeA. In dependent rats, urocortin 3 (0.1 microg/microl and 0.5 microg/microl) decreased ethanol self-administration, with no effect on water self-administration. In nondependent rats, urocortin 3 (0.5 microg/microl) increased ethanol self-administration, with no effect on water self-administration. These data demonstrate an opposing role of the CRF(2) receptor subtype within the CeA in mediating ethanol self-administration in withdrawn, dependent and nondependent rats.

Chronic ethanol exposure increases microtubule content in PC12 cells.

BACKGROUND: Chronic ethanol exposure has been shown to result in changes in neuronal cyto-architecture such as aberrant sprouting and alteration of neurite outgrowth. In PC12 cells, chronic ethanol treatment produces an increase in Nerve Growth Factor (NGF)-induced neurite outgrowth that appears to require the epsilon, but not delta, isoform of Protein Kinase C (PKC). Neurites contain a core of microtubules that are formed from polymerization of free-tubulin. Therefore, it would be expected that an increase in neurite outgrowth would correlate with an increase in microtubule content. We examined the effect of chronic ethanol exposure on microtubule content in PC12 cells and the role of PKC epsilon and delta in ethanol's effect on microtubule levels. RESULTS: Chronic ethanol exposure of wild-type and vector control PC12 cells resulted in a significant increase in microtubule content and a corresponding decrease in free tubulin. There was also a significant increase in microtubule content in PC12 cells expressing a dominate-negative inhibitor of epsilon PKC; cells which have previously been shown to have no ethanol-induced increase in neurite outgrowth. In contrast, ethanol had no effect on microtubule content in PC12 cells expressing a dominate-negative inhibitor of delta PKC. CONCLUSION: These results suggest that chronic ethanol exposure alters the relative ratio of free tubulin to microtubule-associated tubulin, an important component of the cytoskeleton. Further, the data from the PKC dominant-negative cell lines suggest that the effects of ethanol on microtubule content do not correlate with the effects of ethanol on neurite outgrowth. The delta isoform of PKC appears to be necessary for the ethanol-induced increase in microtubule content. These studies demonstrate an effect of chronic ethanol exposure which may contribute to previously documented alterations of neuronal cyto-architecture.