Abstract
Ets1 is an essential transcription factor (TF) for several important physiological processes, including cell proliferation and differentiation. Its recognition of the enhancer region of the TCRα gene is enhanced by the cooperative binding of the Runx1–CBFβ heterodimer, with the cancelation of phosphorylation-dependent autoinhibition. The detailed mechanism of this interesting cooperativity between Ets1 and the Runx1–CBFβ heterodimer is still largely unclear. Here, we investigated the molecular mechanisms of this cooperativity, by using molecular dynamics simulations. Consequently, we detected high flexibility of the loop region between the HI2 and H1 helices of Ets1. Upon Runx1–CBFβ heterodimer binding, this loop transiently adopts various sub-stable conformations in its interactions with the DNA. In addition, a network analysis suggested an allosteric pathway in the molecular assembly and identified some key residues that coincide with previous experimental studies. Our simulations suggest that the cooperative binding of Ets1 and the Runx1–CBFβ heterodimer alters the DNA conformation and induces sub-stable conformations of the HI2–H1 loop of Ets1. This phenomenon increases the flexibility of the regulatory module, including the HI2 helix, and destabilizes the inhibitory form of this module. Thus, we hypothesize that this effect facilitates Ets1–DNA binding and prevents the phosphorylation-dependent DNA binding autoinhibition.
Highlights
The regulation of gene expression by the specific binding of transcription factors (TFs) to regulatory cis-elements is an essential process for living organisms
The time courses of the interatomic distances of Ile321–Leu429 and Ile321–Tyr424 are shown in S7 Fig, and the structure of the regulatory module (RM) is shown in S2 Fig. These results suggest that the cooperative binding with the Runx1–core binding factor β (CBFβ) heterodimer induces large fluctuations of the HI2–H1 loop and the RM, which form many transient interactions
We simulated several molecular models originating from the crystal structure recently solved by Shiina et al [14] in order to elucidate the molecular mechanisms underlying the cooperative binding of Runx1, CBFβ, and Ets1 to the TRCα enhancer region
Summary
The regulation of gene expression by the specific binding of transcription factors (TFs) to regulatory cis-elements is an essential process for living organisms. The three-dimensional (3D) structures of TFs—DNA complexes have shed light on PLOS ONE | DOI:10.1371/journal.pone.0172654 February 23, 2017
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