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Chronic alcohol exposure can affect brain proteins
Identifying proteins may assist in understanding mechanisms of alcoholism
By LOIS BAKER
Contributing Editor
Researchers at UB studying the effects of alcohol on the brain, using zebrafish as a model, have identified several novel central nervous system proteins that are affected by chronic alcohol exposure.
They also confirmed the involvement of additional proteins previously suggested as targets of alcohol toxicity, and observed abnormal behavior in the fish resulting from chronic alcohol exposure.
Results of the research appeared recently in the online edition of the European Journal of Pharmacology.
Five proteins were found to be overexpressed and three were found to be underexpressed. These proteins are thought to be involved in such critical mechanisms as programmed cell death, cholesterol balance, amino acid metabolism, oxidative stress and signal transduction.
"Identification of proteins that show selective changes in abundance after alcohol exposure has the potential to unlock new pathways, both for understanding the mechanisms of alcoholism and alcohol toxicity, as well as its amelioration," said Richard A. Rabin, professor in the Department of Pharmacology and Toxicology and senior author on the study.
Senthilkumar Damodaran, doctoral student in pharmacology, is first author.
The study involved 16 long-fin, striped zebrafish in two trials of eight each, which were placed as a group in a tank with ethyl alcohol for four weeks. Rabin said the researchers chose zebrafish because they are easy to breed and maintain, their DNA sequences are similar to that of humans and they are sensitive to alcohol concentrations.
The concentration of alcohol used is similar to alcohol levels observed in humans, Rabin noted, and is comparable to levels reported in several rodent studies.
"Exposing the fish to alcohol for four weeks has the virtue of being a simple system," he said. "The ethanol concentration and length of exposure can be controlled tightly and applied identically to all subjects. This method also prevents possible complications due to alcohol withdrawal." He noted, however, that it does not reflect the typical situation in humans.
Once in the alcohol solution, the fish were photographed digitally every 30 seconds, and every third image was stored for analysis. Zebrafish normally swim in a cluster in unison, so the procedure allowed nonintrusive monitoring of an inherent behavior.
Processes known as 2-D electrophoresis and MALFI-TOF mass spectrometry were used to identify proteins in the central nervous system that showed increased or decreased expression.
The photographs showed that after a week of alcohol exposure, the fish became less clustered and occupied a larger area of the tank. However, after two weeks of daily exposure, the cluster reformed and behavior returned to normal, suggesting the fish had become alcohol-tolerant.
The abnormal behavior, characterized by increased distance between fish in the group, returned after six weeks exposure, said Rabin, suggesting a progressive increase in behavior disruption.
"We don't know why this change occurred at this point," he said, "but it might indicate accumulated neurotoxic and neurodegenerative effects of chronic alcohol exposure."
Additional researchers on the study were Cynthia A. Dlugos, assistant professor of pathology and anatomical sciences, and Troy D. Wood, professor of chemistry. The research was supported by UB's Interdisciplinary Research and Creative Activities Fund.