Modulating Nucleosomal H3 Tail Dynamics with Lysine and Serine Modifications

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Abstract

Nuclear organization is dynamic and originates from the fundamental subunit of chromatin, the nucleosome. Post-translational modification of nucleosomal histones, particularly within intrinsically disordered histone tail regions, provides a dynamic regulatory mechanism of accessibility for chromatin-templated processes. While the epigenomic impacts of lysine acetylation and serine phosphorylation in the histone H3 tail are well-known, how these charge-altering post-translational modifications (PTMs) alter nucleosomal tail conformational dynamics remains incompletely characterized. Given that the functional implications of these PTMs are, at least in part, a consequence of modified nucleosome conformation, systematically cataloging the impact of histone PTMs on nucleosome dynamics provides crucial insight into both baseline cellular activity and epigenetic dysregulation that occurs in disease. Previously, our lab demonstrated that arginine citrullination mimetics lead to regional increases in H3 tail dynamics within nucleosome core particles. Here, we performed nuclear magnetic resonance spin relaxation experiments to investigate the effects of lysine acetylation and serine phosphorylation on H3 tail picosecond-nanosecond (ps-ns) dynamics. Using lysine-to-glutamine and serine-to-glutamate mutations as acetyllysine and phosphoserine mimetics, respectively, we found that these PTMs increase ps-ns conformational dynamics regionally around the PTM site, with a position-dependent effect. Additionally, we show that the type of PTM influences the extent of these increases: in general, the effect of mimetics trends in the order of phosphorylation ≤ acetylation < citrullination, suggesting a tunable method for altering histone tail dynamics. Taken together, these results illustrate the role of nucleosome conformational dynamics in conveying the effects of epigenomic PTMs, elucidating a mechanism of the histone language.

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