201. Complexities in the role of acetylation dynamics in modifying inducible gene activation parameters
- Author
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Yaoyong Li, Samantha Carrera, Andrew D. Sharrocks, Karol Nowicki-Osuch, Shen Hsi Yang, Syed Murtuza Baker, David G. Spiller, and Amanda O'Donnell
- Subjects
Transcriptional Activation ,Regulation of gene expression ,Epidermal Growth Factor ,AcademicSubjects/SCI00010 ,Lysine ,Gene regulation, Chromatin and Epigenetics ,Acetylation ,Context (language use) ,Biology ,Cell Line ,Cell biology ,Histone Code ,Histone Deacetylase Inhibitors ,Histones ,Histone ,Gene expression ,Genetics ,biology.protein ,Humans ,Allele ,Gene - Abstract
High levels of histone acetylation are associated with the regulatory elements of active genes, suggesting a link between acetylation and gene activation. We revisited this model, in the context of EGF-inducible gene expression and found that rather than a simple unifying model, there are two broad classes of genes; one in which high lysine acetylation activity is required for efficient gene activation, and a second group where the opposite occurs and high acetylation activity is inhibitory. We examined the latter class in more detail using EGR2 as a model gene and found that lysine acetylation levels are critical for several activation parameters, including the timing of expression onset, and overall amplitudes of the transcriptional response. In contrast, DUSP1 responds in the canonical manner and its transcriptional activity is promoted by acetylation. Single cell approaches demonstrate heterogenous activation kinetics of a given gene in response to EGF stimulation. Acetylation levels modify these heterogenous patterns and influence both allele activation frequencies and overall expression profile parameters. Our data therefore point to a complex interplay between acetylation equilibria and target gene induction where acetylation level thresholds are an important determinant of transcriptional induction dynamics that are sensed in a gene-specific manner., Graphical Abstract Graphical AbstractModel showing how acetylation levels driven by the KDAC-KAT equilibrium differentially affects gene activation.
- Published
- 2021