High-throughput determination of RNA tertiary contact thermodynamics by quantitative DMS chemical mapping

Dimethyl sulfate (DMS) chemical mapping is widely used for probing RNA structure, with low reactivity interpreted as Watson-Crick (WC) base pairs and high reactivity as unpaired nucleotides. Despite its widespread use, a quantitative understanding of how DMS reactivity relates to specific RNA 3D structural features remains incomplete. To address this gap, we systematically analyzed DMS reactivity patterns with a massive library of 7,500 RNA constructs containing two-way junctions with known 3D structures. Our results reveal that DMS reactivity exists on a continuous spectrum rather than discrete high and low bins. Approximately 10% overlap in reactivity between WC and non-WC nucleotides demonstrates that simple thresholds cannot accurately determine base-pairing status. In flanking WC pairs, DMS reactivity correlates with base stacking strength and junction dynamics. For non-WC nucleotides, increased hydrogen bonding and decreased solvent accessibility led to WC-like DMS protection. Most significantly, we discover that DMS reactivity in non-canonical pairs strongly correlates with atomic distances and base pair geometry, enabling discrimination between different 3D conformations. These quantitative relationships establish novel metrics for evaluating RNA structural models and provide a new framework for incorporating DMS reactivity patterns into structure prediction algorithms.

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Simultaneous mapping of RNA secondary, tertiary, and quaternary structure in living cells by multi-site DMS probing

Saleem,

Miller,

Kearns

et al. 2024

Preprint

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Identifying tertiary structures and protein binding sites on RNA molecules remains a key challenge in RNA biology. We report a new chemical probing strategy termed multi-site DMS-MaP (msDMS-MaP) that exploits base tautomerization during mutational profiling reverse-transcription to measure typically invisible DMS-induced modifications at the N7 position of G. These N7-G modifications are now resolved concurrently with conventional N1 and N3 modifications with only minor modifications to established protocols, providing a multi-dimensional, single-molecule readout of RNA structure. We show that N7-G reactivity specifically reports on RNA tertiary and quaternary structure, enabling identification of diverse, functionally significant motifs such as cooperatively folding tertiary domains and protein binding sites in living cells. We apply msDMS-MaP to obtain a map of the quaternary structural ensemble of the 7SK non-coding snRNP, revealing unique protein binding sites across three 7SK structural isoforms. msDMS-MaP represents a broadly applicable strategy for enhanced RNA functional motif discovery and characterization.

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High-throughput determination of RNA tertiary contact thermodynamics by quantitative DMS chemical mapping

Cited by 3 publications

References 46 publications

Conformational penalties: New insights into nucleic acid recognition

Conformational penalties: New insights into nucleic acid recognition

A quantitative framework for structural interpretation of DMS reactivity

Simultaneous mapping of RNA secondary, tertiary, and quaternary structure in living cells by multi-site DMS probing

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