Abstract
In this paper we describe an approach that combines stable isotope labeling of amino acids in cells culture, high mass accuracy liquid chromatography tandem mass spectrometry and a novel data analysis approach to accurately determine relative peptide post-translational modification levels. This paper describes the application of this approach to the discovery of novel histone modification crosstalk networks in Saccharomyces cerevisiae. Yeast histone mutants were generated to mimic the presence/absence of 44 well-known modifications on core histones H2A, H2B, H3, and H4. In each mutant strain the relative change in H3 K79 methylation and H3 K56 acetylation were determined using stable isotope labeling of amino acids in cells culture. This approach showed relative changes in H3 K79 methylation and H3 K56 acetylation that are consistent with known histone crosstalk networks. More importantly, this study revealed additional histone modification sites that affect H3 K79 methylation and H3 K56 acetylation.
Highlights
Histone post-translational modifications play a crucial role in stabilizing chromosomal structure and regulating gene transcription [1,2,3]
By combining this method with the site-directed mutagenesis of yeast core histones, we identified multiple mutations that affect the level of H3 K79 methylation and H3 K56 acetylation
The second type of mechanism would involve effects on other enzymes that modulate H3 K79 methylation and H3 K56 acetylation. This would include interactions, in trans, that would regulate the binding or catalytic activity of histone demethylases (HDMs) and histone deacetylases (HDACs) that are specific for these modifications
Summary
Histone post-translational modifications play a crucial role in stabilizing chromosomal structure and regulating gene transcription [1,2,3]. The methylation of histone H3 can be regulated in trans by elements on the NH2-terminal tail of histone H4 and histone H2A [23, 25, 26]. In this paper we examined histone crosstalk networks for H3 K79 methylation and H3 K56 acetylation, which are among the most intensively studied histone modifications (14, 30 – 36). ChIP has been widely used to determine the abundance of H3 K56 acetylation to study its function in transcriptional regulation [34, 45]. Mass spectrometry has been used to determine the relative abundance of K56 acetylation in yeast by dividing the amount of acetylated peptide by the sum of acetylated and unacetylated peptides detected by MALDITOF mass spectrometry [36]
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