Abstract
Genomes contain rare guanine-rich sequences capable of assembling into four-stranded helical structures, termed G-quadruplexes, with potential roles in gene regulation and chromosome stability. Their mechanical unfolding has only been reported to date by all-atom simulations, which cannot dissect the major physical interactions responsible for their cohesion. Here, we propose a mesoscopic model to describe both the mechanical and thermal stability of DNA G-quadruplexes, where each nucleotide of the structure, as well as each central cation located at the inner channel, is mapped onto a single bead. In this framework we are able to simulate loading rates similar to the experimental ones, which are not reachable in simulations with atomistic resolution. In this regard, we present single-molecule force-induced unfolding experiments by a high-resolution optical tweezers on a DNA telomeric sequence capable of adopting a G-quadruplex conformation. Fitting the parameters of the model to the experiments we find a correct prediction of the rupture-force kinetics and a good agreement with previous near equilibrium measurements. Since G-quadruplex unfolding dynamics is halfway in complexity between secondary nucleic acids and tertiary protein structures, our model entails a nanoscale paradigm for non-equilibrium processes in the cell.
Highlights
G-Quadruplexes (G4) are non-canonical conformations of DNA or RNA sequences rich in guanine nucleobases
The mechanical stability of G4s have been studied at the single molecule level by means of AFM and optical tweezers (OT)[7,8,9,10,11,12]
We previously studied the mechanical unfolding of a fragment of the human telomeric sequence that can be folded in different geometries by using Steered Molecular Dynamics
Summary
G-Quadruplexes (G4) are non-canonical conformations of DNA or RNA sequences rich in guanine nucleobases. We showed that the unfolding pattern in the force-extension curves is correlated with the loss of coordination of the central ions in the G4 and that its stability is significantly decreased if the ions are removed[20] These results cannot be compared directly with the experimental results due to the high pulling velocity used in this molecular dynamics simulation (around 6 orders of magnitude higher than in the experiments), which is known to affect the unfolding forces. Rebic et al developed a mesoscopic model following a bottom up approach[22] Their model presents three different beads: one bead for the guanines, another for the nucleotides in the loop, and the last one for the ions, which interact by means of tabulated potentials
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