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Multistate B- to A- transition in protein-DNA Binding – How well is it described by current AMBER force fields?

Petr Jurečka, Marie Zgarbová, Filip Černý, Jan Salomon

2024Journal of Biomolecular Structure and Dynamics11 citationsDOIOpen Access PDF

Abstract

When DNA interacts with a protein, its structure often undergoes a significant conformational adaptation, usually involving a transition from B-DNA towards the A-DNA form. This is not a two-state, but rather a multistate transition. The A- and B- forms differ mainly in sugar pucker (north/south) and glycosidic torsion χ (anti/high-anti). The combination of A-like pucker and B-like χ (and vice versa) represents the nature of the intermediate states between the pure A- and B- forms. Here we study how the A/B equilibrium and the A/B intermediate states at protein-DNA interfaces are modeled by current AMBER force fields. Eight diverse protein-DNA complexes and their naked (unbound) DNAs were simulated with OL15 and bsc1 force fields and an experimental combination OL15χOL3. We found that while the geometries of the A-like intermediate states agree well with the native X-ray geometries, their populations (stabilities) are significantly underestimated. Different force fields predict different propensities for A-like states growing in the order OL15 < bsc1 < OL15χOL3, yet all underestimate A-like form populations. Interestingly, the force fields seem to predict the correct sequence-dependent A-form propensity, as they predict larger populations of the A-like form in unbound DNA in those steps that acquire A-like conformations in protein-DNA complexes. The instability of A-like geometries in current force fields significantly alters the geometry of simulated protein-DNA complexes and destabilizes the binding motif, suggesting that refinement is required to improve description of protein-DNA interactions in AMBER force fields.

Topics & Concepts

DNAGlycosidic bondChemistryA-DNAChemical physicsCrystallographyForce field (fiction)BiophysicsPhysicsBiologyBiochemistryEnzymeQuantum mechanicsDNA and Nucleic Acid ChemistryProtein Structure and DynamicsRNA and protein synthesis mechanisms