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Abstract
Acetylation of lysine residues in histone tails is associated with gene transcription. Because histone tails are structurally flexible and intrinsically disordered, it is difficult to experimentally determine the tail conformations and the impact of acetylation. In this work, we performed simulations to sample H3 tail conformations with and without acetylation. The results show that irrespective of the presence or absence of the acetylation, the H3 tail remains in contact with the DNA and assumes an α-helix structure in some regions. Acetylation slightly weakened the interaction between the tail and DNA and enhanced α-helix formation, resulting in a more compact tail conformation. We inferred that this compaction induces unwrapping and exposure of the linker DNA, enabling DNA-binding proteins (e.g., transcription factors) to bind to their target sequences. In addition, our simulation also showed that acetylated lysine was more often exposed to the solvent, which is consistent with the fact that acetylation functions as a post-translational modification recognition site marker.
Highlights
In eukaryotic cells, the genome is compactly stored within the nucleus as a complex with proteins
In conventional molecular dynamics (MD) simulations, the conformations of histone tails cannot be sufficiently sampled within a practical simulation time, because attractive electrostatic interactions strongly bind the tails to the DNA
We assessed the interaction of the H3 tail and the DNA based on the contact surface area (CSA) between the two
Summary
The genome is compactly stored within the nucleus as a complex with proteins. The basic structural unit of the complex is the nucleosome, which is composed of 146 or 147 base pairs of DNA wrapped around a histone octamer consisting of two copies each of histones H3, H4, H2A and H2B[1]. PTM occurs most often in the N-terminal regions (tails) of histones, and the precise locations of PTM are closely linked to specific DNA functions and biological events [2]. This prompted Strahi and Allis to propose the histone code hypothesis[3]: “multiple histone modifications, acting in a combinatorial or sequential fashion on one or multiple histone tails, specify unique downstream functions.”. Because the tails are intrinsically disordered with no static conformation, details of the molecular mechanism by which PTM exerts its effects remain unclear[6, 7], and there are no decisive clues as to which extent PTM affects the conformations of histone tails, nucleosomes or chromatin
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