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Probing conformational transitions towards mutagenic Watson–Crick-like G·T mismatches using off-resonance sugar carbon R1ρ relaxation dispersion

Atul Rangadurai, Eric S. Szymanski, Isaac J. Kimsey, Honglue Shi, Hashim M. Al‐Hashimi

2020Journal of Biomolecular NMR25 citationsDOIOpen Access PDF

Abstract

Abstract NMR off-resonance R 1ρ relaxation dispersion measurements on base carbon and nitrogen nuclei have revealed that wobble G·T/U mismatches in DNA and RNA duplexes exist in dynamic equilibrium with short-lived, low-abundance, and mutagenic Watson–Crick-like conformations. As Watson–Crick-like G·T mismatches have base pairing geometries similar to Watson–Crick base pairs, we hypothesized that they would mimic Watson–Crick base pairs with respect to the sugar-backbone conformation as well. Using off-resonance R 1ρ measurements targeting the sugar C3′ and C4′ nuclei, a structure survey, and molecular dynamics simulations, we show that wobble G·T mismatches adopt sugar-backbone conformations that deviate from the canonical Watson–Crick conformation and that transitions toward tautomeric and anionic Watson–Crick-like G·T mismatches restore the canonical Watson–Crick sugar-backbone. These measurements also reveal kinetic isotope effects for tautomerization in D 2 O versus H 2 O, which provide experimental evidence in support of a transition state involving proton transfer. The results provide additional evidence in support of mutagenic Watson–Crick-like G·T mismatches, help rule out alternative inverted wobble conformations in the case of anionic G·T − , and also establish sugar carbons as new non-exchangeable probes of this exchange process.

Topics & Concepts

Molecular Structure of Nucleic Acids: A Structure for Deoxyribose Nucleic AcidChemistryTautomerBase pairWobble base pairResonance (particle physics)Speed wobbleCrystallographyStereochemistryDNATransfer RNARNAAtomic physicsPhysicsBiochemistryQuantum mechanicsGeneDNA and Nucleic Acid ChemistryRNA and protein synthesis mechanismsProtein Structure and Dynamics