A quantitative model predicts how m6A reshapes the kinetic landscape of nucleic acid hybridization and conformational transitions
Bei Liu, Honglue Shi, Atul Rangadurai, Felix Nußbaumer, Chia-Chieh Chu, Kevin Erharter, David A. Case, Christoph Kreutz, Hashim M. Al‐Hashimi
Abstract
ABSTRACT N 6 -methyladenosine (m 6 A) is a post-transcriptional modification that controls gene expression by recruiting proteins to RNA sites. The modification also slows biochemical processes through mechanisms that are not understood. Using temperature-dependent (20°C–65°C) NMR relaxation dispersion, we show that m 6 A pairs with uridine with the methylamino group in the anti conformation to form a Watson-Crick base pair that transiently exchanges on the millisecond timescale with a singly hydrogen-bonded low-populated (1%) mismatch-like conformation in which the methylamino group is syn . This ability to rapidly interchange between Watson-Crick or mismatch-like forms, combined with different syn : anti isomer preferences when paired (~1:100) versus unpaired (~10:1), explains how m 6 A robustly slows duplex annealing without affecting melting at elevated temperatures via two pathways in which isomerization occurs before or after duplex annealing. Our model quantitatively predicts how m 6 A reshapes the kinetic landscape of nucleic acid hybridization and conformational transitions, and provides an explanation for why the modification robustly slows diverse cellular processes.