Alcohol Withdrawal Increases Protein Kinase A Activity in the Rat Inferior Colliculus.

BACKGROUND: Cyclic AMP-dependent protein kinase A (PKA) signaling is a key target for the action of alcohol and may therefore play a role in the pathophysiology of alcohol withdrawal seizures (AWSs). Here, we investigated the role of PKA activity with respect to increased seizure susceptibility in rats that were subjected to alcohol withdrawal. METHODS: Adult male Sprague Dawley rats received 3 daily doses of ethanol (EtOH) (or vehicle) for 4 consecutive days. Rats were then tested for susceptibility to acoustically evoked AWSs 3, 24, and 48 hours after the last alcohol dose. In separate experiments, the inferior colliculus (IC) was collected at these same time points from rats subjected to alcohol withdrawal and control rats following alcohol withdrawal. PKA activity, catalytic Cα (PKACα ) protein, regulatory RIIα (PKARIIα ) protein, and RIIß (PKARIIß ) protein were measured in the IC. Lastly, in situ pharmacological studies were performed to evaluate whether inhibiting PKA activity in the IC suppressed AWSs. RESULTS: In the EtOH-treated group, AWSs were observed at the 24-hour time point, but not at the 3-hour or 48-hour time points. In the IC, PKA activity was significantly higher both 3 hours (i.e., before AWS susceptibility) and 24 hours after the last alcohol dose (when AWS susceptibility peaked) than in control rats. Consistent with these findings, protein levels of the PKACα subunit were significantly increased in the IC both 3 and 24 hours after the last alcohol dose. Lastly, in situ inhibition of PKA activity within the IC suppressed AWSs. CONCLUSIONS: The increase in PKA activity and PKACα protein expression in the IC preceded the occurrence of AWSs, and inhibiting PKA activity within the IC suppressed acoustically evoked AWSs. Together, these findings suggest that altered PKA activity plays a key role in the pathogenesis of AWSs.

Alterations in homocysteine metabolism among alcohol dependent patients--clinical, pathobiochemical and genetic aspects.

Addiction research focusing on homocysteine metabolism and its association with aspects of alcohol dependence has revealed important findings. Recent literature on this topic has been taken into account for the review provided. Methylenetetrahydrofolate reductase (MTHFR) is a key enzyme in the homocysteine metabolism. Plasma homocysteine levels are influenced by the single-nucleotide polymorphism (SNP) MTHFR C677T. Besides genetic factors, environmental factors have an impact on homocysteine plasma levels too. Thus, chronic alcohol intake is associated with elevated homocysteine plasma concentrations. Elevation of plasma homocysteine concentration is considered as a predictor for the occurrence of alcohol withdrawal seizures and--as homocysteine is a cardiovascular risk factor--might contribute to the higher risk for myocardial infarction among alcohol dependent patients. Homocysteine acts as an N-methyl-D-aspartate (NMDA) receptor agonist and has excitotoxic effects. Furthermore, it has been demonstrated that homocysteine has neurotoxic effects especially on dopaminergic neurons. As the rewarding effects of alcohol are mediated by the dopaminergic system, a homocysteine-dependent impairment of the reward system possibly leads to an altered drinking behaviour according to the deficit hypothesis of addiction. Homocysteine is involved in the metabolism of methyl groups and DNA-methylation plays a role in regulation of gene expression. Therefore it has been suggested that homocysteine is an important epigenetic factor. It remains to be determined whether alcohol dependent patients benefit from homocysteine lowering strategies, e.g., via supplementation of folate, vitamin B6 and B12. In this respect it is not clear yet, if a supplementation therapy can reduce the risk for the occurrence of alcohol withdrawal seizures.

ERK regulation in chronic ethanol exposure and withdrawal.

The extracellular signal regulated protein kinases (ERKs), also known as mitogen-activated protein kinases (MAPK) of 42 and 44 kd, play a crucial role in the induction of various forms of neural plasticity. Ethanol induces long-lasting functional changes that are more severe following repeated exposure and may involve intracellular signal transduction mechanisms. Therefore, we investigated the regulation of the ERK signal transduction pathway in models of continuous and intermittent ethanol exposure and withdrawal. Moderate blood alcohol levels (BALs) reduced ERK activation in most of the brain regions studied. Conversely, during withdrawal, activation of ERK was increased in most areas with some regional variations in the levels and kinetics of induction. The most dramatic effects were observed in the amygdala, the cerebellum, the striatum and the hippocampus. In the amygdala and the cerebellum, the activation of ERK observed during withdrawal was significantly higher after intermittent ethanol exposure than after continuous exposure, suggesting the establishment of a form of sensitization to the effects of withdrawal on ERK regulation. Thus the dysregulation of the ERK pathway could contribute to escalation of withdrawal symptoms induced by repeated withdrawal and possibly to the neuroadaptative changes believed to underlie progression towards addiction.

Reduced ethanol withdrawal severity and altered withdrawal-induced c-fos expression in various brain regions of mice lacking protein kinase C-epsilon.

Withdrawal from chronic ethanol consumption can be accompanied by motor seizures, which may be a result of altered GABA(A) receptor function. Recently, we have generated and characterized mice lacking the epsilon isoform of protein kinase C as being supersensitive to the behavioral and biochemical effects of positive GABA(A) receptor allosteric modulators, including ethanol. The aim of the present study was to determine whether protein kinase C-epsilon null mutant mice display altered seizure severity during alcohol withdrawal. In addition, we used c-fos immunohistochemistry immediately following seizure assessment to identify potential brain regions involved in any observed differences in withdrawal severity. Mice were allowed to consume an ethanol-containing or control liquid diet as the sole source of food for 14 days. During the 7-h period following removal of the diet, both ethanol-fed wild-type and protein kinase C-epsilon null mutant mice displayed an overall increase in Handling-Induced Convulsion score versus control-fed mice. However, at 6 and 7h following diet removal, the Handling-Induced Convulsion score was reduced in ethanol-fed protein kinase C-epsilon null mutant mice compared to ethanol-fed wild-type mice. Ethanol-fed protein kinase C-epsilon null mutant mice also exhibited a decrease in the number of Fos-positive cells in the lateral septum, and an increase in the number of Fos-positive cells in the dentate gyrus, mediodorsal thalamus, paraventricular nuclei of the thalamus and hypothalamus, and substantia nigra compared to ethanol-fed wild-type mice. These data demonstrate that deletion of protein kinase C-epsilon results in diminished progression of ethanol withdrawal-associated seizure severity, suggesting that selective pharmacological inhibitors of protein kinase C-epsilon may be useful in the treatment of seizures during alcohol withdrawal. These data also provide insight into potential brain regions involved in generation or suppression of ethanol withdrawal seizures.

Glial differences between naïve withdrawal seizure-prone and -resistant mice.

BACKGROUND: Withdrawal seizure-prone (WSP) and withdrawal seizure-resistant (WSR) mice were bred in replicate (i.e., WSP-1 and WSP-2) to exhibit differences in handling-induced convulsion severity during ethanol withdrawal. METHODS: We examined the role of the glutamatergic system in susceptibility to ethanol-withdrawal convulsions in naive mice by measuring the density of immunolabeling for several glutamate transporters and the glutamate-metabolizing enzyme, glutamine synthetase. The density of glial fibrillary acidic protein immunolabeling (a marker of glial structure) and cytochrome oxidase activity (a marker of neuronal activity) were also characterized in naive mice. RESULTS: We observed a significantly greater density of immunolabeling for the glial transporter, glutamate/aspartate transporter, in CA1 subfield of the hippocampus (CA1) of naive WSP-2 mice as compared to WSR-2 mice. No other significant differences were observed. However, as compared to WSR mice, naive WSP mice exhibited a trend toward (a) greater immunolabeling for the glial glutamate transporter, glutamate transporter-1, in CA3, (b) greater immunolabeling for glial-specific glutamate-metabolizing enzyme, glutamine synthetase, in CA1 (replicate-2 only), and (c) less immunolabeling for the glial structural protein, glial fibrillary acidic protein, in all brain regions tested. In contrast, no trends or significant differences in the labeling density for the neuronal transporter, excitatory amino acid carrier 1, or the neuronal activity marker, cytochrome oxidase, were observed between the selected lines. CONCLUSIONS: These data suggest that the glutamatergic system and glia may play a pivotal role in the increased susceptibility to handling-induced convulsions observed in WSP mice.