Abstract
Temperature is one of the most fundamental physical variables governing RNA folding, yet its effects at low temperature remain incompletely understood. Recent single-molecule studies indicate that lowering temperature below a characteristic threshold (~ 20 °C) alters the folding pathways and promotes the population of non-native intermediates, including non-native conformations not predicted by standard secondary-structure models. Here, we combine temperature-controlled optical tweezers with computational free-energy landscape analysis to examine how the architecture of the HIV-1 TAR RNA hairpin modulates folding in this low-temperature regime. We show that decreasing temperature stabilizes the native hairpin but, below ~ 20 °C, promotes two distinct classes of misfolded intermediates dependent on the presence of the conserved three-nucleotide bulge. Together, the experimental data and the free-energy landscape analysis indicate that the presence of the bulge, not the loop, underlies the emergence of these low-temperature misfolded intermediates, accounting for their distinct mechanical signatures compared to those reported for RNA hairpins with a long loop.
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Acknowledgements
Acknowledgments. This work was supported by Fondecyt Grant No. 1231276 (Agencia Nacional de Investigación y Desarrollo, ANID, Chile). R.R. acknowledges financial support from ANID, Chile, through the Doctorado Nacional Fellowship No. 21220918. E.R. was supported by CONICET and grants PIP 2022 and PICT 2020–21058 (Argentina). We thank Steven Smith and Christian A. M. Wilson for valuable discussions and technical advice. Fondo de Apoyo a Publicaciones Científicas y Gestión de Patentes, Facultad de Ciencias Químicas y Farmacéuticas, Universidad de Chile.
Funding
Fondecyt Grant 1231276 (Agencia Nacional de Investigación y Desarrollo, ANID, Chile), Doctorado Nacional Fellowship No. 21220918, CONICET and grants PIP 2022 and PICT 2020–21058 (Argentina).
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Rivera, R., Valdebenito, C.E., Roman, E.A. et al. Single-molecule analysis reveals low-temperature misfolding in HIV-1 TAR RNA. Sci Rep (2026). https://doi.org/10.1038/s41598-026-49876-3
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DOI: https://doi.org/10.1038/s41598-026-49876-3
