AI Article Synopsis
- Structural plasticity is essential for RNA function, but current methods struggle to quantitatively analyze RNAs with multiple structural forms.
- Combining NMR spectroscopy and chemical probing allows for visualization of a two-state conformational ensemble in the central stem-loop 3 (SL3) of 7SK RNA, crucial for transcription regulation.
- The research shows SL3 can exchange between two distinct states, and both methods provide consistent data, highlighting the importance of structural dynamics in RNA and the effectiveness of integrating these two techniques for better analysis.
Article Abstract
Structural plasticity is integral to RNA function; however, there are currently few methods to quantitatively resolve RNAs that have multiple structural states. NMR spectroscopy is a powerful approach for resolving conformational ensembles but is size-limited. Chemical probing is well-suited for large RNAs but provides limited structural and kinetics information. Here, we integrate the two approaches to visualize a two-state conformational ensemble for the central stem-loop 3 (SL3) of 7SK RNA, a critical element for 7SK RNA function in transcription regulation. We find that the SL3 distal end exchanges between two equally populated yet structurally distinct states in both isolated SL3 constructs and full-length 7SK RNA. We rationally designed constructs that lock SL3 into a single state and demonstrate that both chemical probing and NMR data fit to a linear combination of the two states. Comparison of vertebrate 7SK RNA sequences shows either or both states are highly conserved. These results provide new insights into 7SK RNA structural dynamics and demonstrate the utility of integrating chemical probing with NMR spectroscopy to gain quantitative insights into RNA conformational ensembles.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10810284 | PMC |
| http://dx.doi.org/10.1093/nar/gkad1159 | DOI Listing |
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