Abstract
The C‐terminal domain (CTD) of tumor suppressor protein p53 is an intrinsically disordered region that binds to various partner proteins, where lysine of CTD is acetylated/nonacetylated and histidine neutralized/non‐neutralized. Because of the flexibility of the unbound CTD, a free‐energy landscape (FEL) is a useful quantity for determining its statistical properties. We conducted enhanced conformational sampling of CTD in the unbound state via virtual system coupled multicanonical molecular dynamics, in which the lysine was acetylated or nonacetylated and histidine was charged or neutralized. The fragments were expressed by an all‐atom model and were immersed in an explicit solvent. The acetylation and charge‐neutralization varied FEL greatly, which might be convenient to exert a hub property. The acetylation slightly enhanced alpha‐helix structures that are more compact than sheet/loop conformations. The charge‐neutralization produced hairpins. Additionally, circular dichroism experiments confirmed the computational results. We propose possible binding mechanisms of CTD to partners by investigating FEL. © 2016 The Authors. Journal of Computational Chemistry Published by Wiley Periodicals, Inc.
Highlights
An intrinsically disordered region (IDR) of a protein is highly flexible in physiological conditions unless interacting with its partner molecule.[1]
Because the high flexibility is an inherent property of IDR, investigation of the conformational ensemble is necessary to elucidate the nature of IDR
The shape of the free-energy landscape varied depending on the K382 acetylation and/or the histidine 380 (H380) neutralization in C-terminal domain (CTD)
Summary
An intrinsically disordered region (IDR) of a protein is highly flexible in physiological conditions unless interacting with its partner molecule.[1] Structurally ordered proteins are well known to exert their biological functions through well-defined quaternary, tertiary, and secondary structures. Signal transduction is a typical function of IDR,[2] where a single IDR interacts with different partner molecules to regulate the signal transduction. This multipartner interaction property is called a hub property.[3] IDRs are related to some diseases such as cancer, diabetes, and neurodegenerative disease.[4] IDRs are an important subject related to biology, biophysics, and medical science
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