Background
Epigenetic dysregulation through ethanol (EtOH)-induced changes in DNA methylation and histone modifications has been implicated in several alcohol-related disorders such as alcoholic liver disease. EtOH metabolism in the liver
Conclusions
These data provide the first quantitative evidence of how hepatic EtOH metabolism directly influences histone lysine acetylation in a site-specific manner and may influence EtOH-induced gene expression through these transcriptionally activating chromatin marks.
Methods
Eight-week-old male C57BL/6J mice were gavaged using a bolus dose of either 13 C2 -labeled EtOH (5 g/kg) or maltose dextrin. Blood and livers were collected at 0, 4, and 24 hours followed by histone protein enrichment and derivatization using acid extraction and propionylation, respectively. Metabolic tracing and relative quantitation of acetylated histone proteins were performed using a hybrid quadrupole-orbitrap mass spectrometer. Data were analyzed using MaxQuant, Xcalibur Qual Browser, and the Bioconductor package "mzR." The contribution of EtOH to histone acetylation was quantified using the change in relative abundance of stable isotope incorporation in acetylated peptides detected by MS.
Results
Data show significant incorporation of the EtOH-derived 13 C2 -label into N-terminal lysine acetylation sites on histones H3 and H4 after 4 hours, with rapid turnover of labeled histone acetylation sites and return to endogenous levels at 24 hours postgavage. Moreover, site-specific selectivity was observed in regard to label incorporation into certain lysine acetylation sites as determined by tandem mass spectrometry and comparison to isotope simulations. Conclusions: These data provide the first quantitative evidence of how hepatic EtOH metabolism directly influences histone lysine acetylation in a site-specific manner and may influence EtOH-induced gene expression through these transcriptionally activating chromatin marks.