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.

The interactive effect of alcohol and nicotine on NGF-treated pheochromocytoma cells.

Previous studies have reported that alcohol exposure reduces the number of neuronal-like pheochromocytoma (PC12) cells in culture. In this study, the interactive effect of coexposure of alcohol and nicotine on PC12 cell numbers was examined in comparison with the effect derived from alcohol or nicotine exposure individually. Moreover, the role of apoptosis in mediating changes in PC12 cell numbers was also investigated. It was hypothesized that alcohol would result in cell loss, and the presence of nicotine would attenuate the damaging effects of alcohol. PC12 cells were exposed to alcohol (100 mM), nicotine (10 microM), or both alcohol and nicotine for 24, 48, 72, or 96 h. Caspase-3 activity and DNA fragmentation, markers for apoptotic cell death, were measured to determine the role of apoptosis in mediating decreases in PC12 cell numbers. The findings indicated that both alcohol and nicotine exposure significantly decreased PC12 cell numbers when compared with the control treatment. Furthermore, the coexposure of these two drugs caused a significantly greater decrease in cell numbers when compared with cells exposed to either alcohol or nicotine alone. This additive effect was related to the duration of exposure with a marked reduction in cell numbers following 96 h of coexposure to alcohol and nicotine. Neither alcohol nor nicotine exposure appeared to alter caspase-3 activity or DNA fragmentation levels, suggesting that the reduction in PC12 cell numbers following alcohol and/or nicotine exposure may possibly be due to factors other than apoptosis, such as interference with proliferation rates.

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.

Ethanol modulates nicotine-induced upregulation of nAChRs.

The use of alcohol and nicotine are highly correlated, suggesting an underlying biochemical interaction. Chronic nicotine exposure results in a deactivation and subsequent upregulation of the expression of nicotinic acetylcholine receptors (nAChRs). Upregulation is thought to represent certain aspects of physical dependence on nicotine. If alcohol also alters nAChR expression or modulates the nicotine-induced upregulation, it could partially explain the high rate of co-abuse of these two drugs. We examined the effects of ethanol on the expression and nicotine-induced upregulation of nAChRs in two cell lines expressing different receptor subtypes. As measured by ligand binding, ethanol initially decreased nAChR expression in M10 cells but increased expression with a more chronic exposure. In the presence of nicotine, the effect of ethanol was similar; initially acting to blunt the upregulation of receptor expression caused by nicotine but enhancing the upregulation with 96 h of exposure. The upregulation of nAChRs was long lasting, remaining above control levels for as long as 7 days following removal of nicotine and ethanol. In PC12 cells, ethanol increased expression at all time points examined. A protein phosphatase inhibitor reduced nicotine-induced upregulation and a PKC inhibitor blocked the ethanol-induced decrease in nAChR expression. These data suggest that ethanol and nicotine interact at the level of the PKC pathway to regulate expression of nAChRs.

Melatonin inhibition of nicotine-stimulated dopamine release in PC12 cells.

Melatonin, a pineal hormone, modifies numerous physiologic processes including circadian rhythms and sleep. In specific tissues, melatonin appears to have an inverse relationship with dopamine. To examine this relationship, a pheochromocytoma cell line (PC12) was used to determine the extent of melatonin's ability to inhibit nicotine-stimulated dopamine release. Multiple experiments were conducted that examined: (1). the dose response of acute melatonin (5 min); (2). the effects of chronic melatonin (16 h pre-exposure); (3). the effects of prior nicotine or melatonin exposure (5 min) on melatonin's ability to alter dopamine release from a second 5-min nicotine exposure; and (4). the role of melatonin receptors (by pertussis toxin inhibition) on nicotine-stimulated dopamine release. In the dose response studies, melatonin inhibited nicotine-stimulated dopamine release with an ED50 of 8.6 microM. Chronic exposure to melatonin had no effect on melatonin's acute inhibition of nicotine-stimulated dopamine release. Prior nicotine or melatonin exposure had little effect on subsequent melatonin or nicotine exposure, except that the cells exposed to nicotine were not responsive to a second exposure to nicotine. Blockade of melatonin receptor function by pre-exposure to pertussis toxin (16 h) did not prevent melatonin's inhibition of nicotine-stimulated dopamine release. However, the toxin-treated cells were less inhibited by melatonin when compared to control cells suggesting a partial role for melatonin receptors. These results indicate that melatonin can acutely inhibit nicotine-stimulated dopamine release in PC12 cells. This model system allows detailed examination of melatonin's cellular actions as well as supporting a role for melatonin on neuronal dopamine release.

betagamma Dimers mediate synergy of dopamine D2 and adenosine A2 receptor-stimulated PKA signaling and regulate ethanol consumption.

Dopamine release is activated by ethanol and addicting drugs, but molecular mechanisms linking dopaminergic signaling to neuronal responses and drinking behavior are poorly understood. We report that dopamine-D2 receptors induce PKA Calpha translocation and increase CRE-regulated gene expression. Ethanol also activates PKA signaling. Subthreshold concentrations of the D2 agonist NPA and ethanol, without effect alone, together cause synergistic PKA translocation and CRE-mediated gene transcription. D2 or adenosine A2 receptor blockade, pertussis toxin, Rp-cAMPS, or overexpression of dominant-negative peptides that sequester betagamma dimers prevent synergy. Importantly, overexpression of a betagamma inhibitor peptide in the nucleus accumbens strikingly reduces sustained alcohol consumption. We propose that synergy of D2 and A2 confers ethanol hypersensitivity and that betagamma dimers are required for voluntary drinking.

Ethanol-induced translocation of protein kinase A occurs in two phases: control by different molecular mechanisms.

BACKGROUND: Cyclic adenosine monophosphate (cAMP)-dependent protein kinase A (PKA) regulates cellular functions. The specificity of PKA-mediated phosphorylation is determined primarily by PKA localization to sub-cellular sites. Chronic exposure to ethanol causes sustained translocation of the PKA catalytic subunit (C) from the Golgi to the nucleus in NG108-15 cells. Here we find that this is preceded by a transient short-term ethanol-induced translocation of PKA C. Different molecular mechanisms appear to underlie early and late phases of ethanol-induced translocation of PKA subunits. METHODS: The time course and localization of PKA C and regulatory (RII) subunits was assessed by immunocytochemistry in NG108-15 cells in the presence of ethanol, adenosine receptor (A2) blockade, and inhibitors of PKA activity and RNA and protein synthesis. RESULTS: Ethanol induces an early phase (<30 min) of C translocation to the cytoplasm and nucleus. This requires cAMP via adenosine A2 receptor activation. C then returns to the Golgi area after 60 min. A second phase of C translocation occurs during continuing exposure to ethanol (>12 hr). Re-accumulation of nuclear C no longer requires A2 or cAMP. RII also translocates to the nucleus during chronic treatment with ethanol. Both C and RII remain in the nucleus as long as ethanol is present. Unlike the early phase of ethanol induced translocation, the second phase of PKA subunit translocation requires protein and RNA synthesis. CONCLUSIONS: We identify two distinct phases of ethanol-induced PKA translocation which appear to be regulated by different molecular mechanisms. The first requires A2 signaling and cAMP; the later phase requires RNA and protein synthesis. The two phases of ethanol-induced PKA translocation observed in cell lines may contribute to changes in PKA signaling, cAMP-dependent gene expression, and the initiation and maintenance of sustained drinking behavior in experimental animals.