Thermodynamic prediction of RNA cellular activity from sequence via conformational ensembles
Summary
Despite advances in structure prediction from sequence, predicting cellular activity requires conformational ensembles that capture propensities to form functionally active states. Such ensembles remain difficult to measure and even harder to predict. Here, we systematically altered the HIV-1 transactivation response element (TAR) RNA sequence to change its propensity to adopt a functional versus inactive secondary structure and quantified these propensities using proton chemical exchange
Content
# Thermodynamic prediction of RNA cellular activity from sequence via conformational ensembles
*Published: 2026 May 14*
Despite advances in structure prediction from sequence, predicting cellular
activity requires conformational ensembles that capture propensities to form
functionally active states. Such ensembles remain difficult to measure and even
harder to predict. Here, we systematically altered the HIV-1 transactivation
response element (TAR) RNA sequence to change its propensity to adopt a
functional versus inactive secondary structure and quantified these propensities
using proton chemical exchange saturation transfer (1H CEST) NMR without
isotopic labeling. Minor sequence changes shifted the active-state propensity by
∼500-fold, quantitatively predicting 125- to 300-fold changes in binding to the
RNA-binding region of Tat and cellular transactivation. These propensities could
be inferred from secondary-structure prediction algorithms and incorporated into
a thermodynamic framework to quantitatively predict how sequence changes alter
protein-binding affinity and cellular activity in this well-characterized
system. Our findings establish a quantitative thermodynamic framework that links
the RNA sequence to cellular activity through conformational ensembles, setting
the stage for more generalized predictions as computational ensemble modeling
continues to advance.
DOI: 10.1016/j.cell.2026.02.021