Modelling the DNA topology: the effect of the loop bending on G-quadruplex stability

Item Type:	Article
Title:	Modelling the DNA topology: the effect of the loop bending on G-quadruplex stability
Creators Name:	Bergues-Pupo, A.E. and Falo, F. and Fiasconaro, A.
Abstract:	The guanine quadruplexes are DNA/RNA guanine-rich sequences assembled into four-stranded helical structures having important roles in gene regulation and chromosome stability. Their mechanical unfolding has been generally studied with all-atom simulations, which cannot dissect the specific interactions responsible for their cohesion. Recently, we introduced a mesoscopic model able to describe the main thermal and mechanical unfolding features of the G-quadruplex, with no distinction between the different geometrical conformations forming the structure. Under the same model we study here the contribution of the bending potential in the extra-structure bonding (loops). We demonstrate with numerical simulations that the rigidity of the loops can account for the different stabilities of different topologies, specifically the parallel and the antiparallel. In the presence of the bending, the model indicates the antiparallel configuration as the most stable G4 topology, as suggested by the experiments.
Keywords:	Biopolymers, Structures and Conformations, Mechanical Properties (DNA, RNA, Membranes, Bio-Polymers)
Source:	Journal of Statistical Mechanics: Theory and Experiment
ISSN:	1742-5468
Publisher:	IOP Publishing
Volume:	2019
Number:	9
Page Range:	094004
Date:	2 September 2019
Official Publication:	https://doi.org/10.1088/1742-5468/ab3784

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