Simulative and Experimental Characterization of a pH-Dependent Clamp-like DNA Triple-Helix Nanoswitch
journal contributionposted on 2017-04-02, 00:00 authored by Federico Iacovelli, Andrea Idili, Alessandro Benincasa, Davide Mariottini, Alessio Ottaviani, Mattia Falconi, Francesco Ricci, Alessandro Desideri
Here we couple experimental and simulative techniques to characterize the structural/dynamical behavior of a pH-triggered switching mechanism based on the formation of a parallel DNA triple helix. Fluorescent data demonstrate the ability of this structure to reversibly switch between two states upon pH changes. Two accelerated, half microsecond, MD simulations of the system having protonated or unprotonated cytosines, mimicking the pH 5.0 and 8.0 conditions, highlight the importance of the Hoogsteen interactions in stabilizing the system, finely depicting the time-dependent disruption of the hydrogen bond network. Urea-unfolding experiments and MM/GBSA calculations converge in indicating a stabilization energy at pH 5.0, 2-fold higher than that observed at pH 8.0. These results validate the pH-controlled behavior of the designed structure and suggest that simulative approaches can be successfully coupled with experimental data to characterize responsive DNA-based nanodevices.
Experimental CharacterizationpH 8.0.unprotonated cytosineshalf microsecondpH 5.0DNA-based nanodevicesreversibly switchpH-Dependent Clamp-like DNA Triple-Helix NanoswitchFluorescent datasimulative approachesstabilization energypH-controlled behaviortime-dependent disruptionhydrogen bond networkUrea-unfolding experimentsHoogsteen interactionsMMMD simulationssimulative techniquespH changes8.0 conditions