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8THV

FARFAR-NMR ensemble of HIV-1 TAR with apical loop capturing ground and excited conformational states

Summary for 8THV
Entry DOI10.2210/pdb8thv/pdb
NMR InformationBMRB: 31099
DescriptorRNA (29-MER) (1 entity in total)
Functional Keywordsviral rna, hiv-1 tar, excited conformational states, rna
Biological sourceHuman immunodeficiency virus 1
Total number of polymer chains1
Total formula weight9307.56
Authors
Roy, R.,Geng, A.,Shi, H.,Merriman, D.K.,Dethoff, E.A.,Salmon, L.,Al-Hashimi, H.M. (deposition date: 2023-07-18, release date: 2023-08-02, Last modification date: 2024-05-15)
Primary citationRoy, R.,Geng, A.,Shi, H.,Merriman, D.K.,Dethoff, E.A.,Salmon, L.,Al-Hashimi, H.M.
Kinetic Resolution of the Atomic 3D Structures Formed by Ground and Excited Conformational States in an RNA Dynamic Ensemble.
J.Am.Chem.Soc., 145:22964-22978, 2023
Cited by
PubMed Abstract: Knowing the 3D structures formed by the various conformations populating the RNA free-energy landscape, their relative abundance, and kinetic interconversion rates is required to obtain a quantitative and predictive understanding of how RNAs fold and function at the atomic level. While methods integrating ensemble-averaged experimental data with computational modeling are helping define the most abundant conformations in RNA ensembles, elucidating their kinetic rates of interconversion and determining the 3D structures of sparsely populated short-lived RNA excited conformational states (ESs) remains challenging. Here, we developed an approach integrating Rosetta-FARFAR RNA structure prediction with NMR residual dipolar couplings and relaxation dispersion that simultaneously determines the 3D structures formed by the ground-state (GS) and ES subensembles, their relative abundance, and kinetic rates of interconversion. The approach is demonstrated on HIV-1 TAR, whose six-nucleotide apical loop was previously shown to form a sparsely populated (∼13%) short-lived (lifetime ∼ 45 μs) ES. In the GS, the apical loop forms a broad distribution of open conformations interconverting on the pico-to-nanosecond time scale. Most residues are unpaired and preorganized to bind the Tat-superelongation protein complex. The apical loop zips up in the ES, forming a narrow distribution of closed conformations, which sequester critical residues required for protein recognition. Our work introduces an approach for determining the 3D ensemble models formed by sparsely populated RNA conformational states, provides a rare atomic view of an RNA ES, and kinetically resolves the atomic 3D structures of RNA conformational substates, interchanging on time scales spanning 6 orders of magnitude, from picoseconds to microseconds.
PubMed: 37831584
DOI: 10.1021/jacs.3c04614
PDB entries with the same primary citation
Experimental method
SOLUTION NMR
Structure validation

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