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Universality in RNA and DNA deformations induced by salt, temperature change, stretching force, and protein binding

Fujia Tian, Chen Zhang, Er-Chi Zhou, Hailong Dong, Zhi-Jie Tan, Xinghua Zhang, Liang Dai

2023Proceedings of the National Academy of Sciences32 citationsDOIOpen Access PDF

Abstract

Nucleic acid deformations play important roles in many biological processes. The physical understanding of nucleic acid deformation by environmental stimuli is limited due to the challenge in the precise measurement of RNA and DNA deformations and the complexity of interactions in RNA and DNA. Magnetic tweezers experiments provide an excellent opportunity to precisely measure DNA and RNA twist changes induced by environmental stimuli. In this work, we applied magnetic tweezers to measure double-stranded RNA twist changes induced by salt and temperature changes. We observed RNA unwinds when lowering salt concentration, or increasing temperature. Our molecular dynamics simulations revealed the mechanism: lowering salt concentration or increasing temperature enlarges RNA major groove width, which causes twist decrease through twist-groove coupling. Combining these results with previous results, we found some universality in RNA and DNA deformations induced by three different stimuli: salt change, temperature, and stretching force. For RNA, these stimuli first modify the major groove width, which is transduced into twist change through twist-groove coupling. For DNA, these stimuli first modify diameter, which is transduced into twist change through twist-diameter coupling. Twist-groove coupling and twist-diameter coupling appear to be utilized by protein binding to reduce DNA and RNA deformation energy cost upon protein binding.

Topics & Concepts

TwistRNADNANucleic acidMagnetic tweezersBiophysicsConformational changeChemical physicsUniversality (dynamical systems)Coupling (piping)ChemistryCrystallographyPhysicsMaterials scienceBiologyBiochemistryCondensed matter physicsComposite materialGeometryGeneMathematicsDNA and Nucleic Acid ChemistryBacteriophages and microbial interactionsRNA and protein synthesis mechanisms