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Machine learning-augmented molecular dynamics simulations (MD) reveal insights into the disconnect between affinity and activation of ZTP riboswitch ligands

  1. Author:
    Fullenkamp, Christopher
    Mehdi, Shams
    Jones, Christopher
    Tenney, Logan
    Pichling, Patricio
    Prestwood, Peri R
    Ferré-D'Amaré, Adrian R
    Tiwary, Pratyush
    Schneekloth,John

  2. Author Address

    National Cancer Institute Center for Cancer Research, Chemical Biology Laboratory, UNITED STATES OF AMERICA., University of Maryland, Biophysics, UNITED STATES OF AMERICA., National Heart Lung and Blood Institute Division of Intramural Research, Laboratory of Nucleic Acids, UNITED STATES OF AMERICA., University of Maryland at College Park: University of Maryland, Chemistry and Biochemistry, UNITED STATES OF AMERICA., National Cancer Institute, Chemical Biology Laboratory, Frederick National Lab, Building 376, Room 225C, 21702, Frederick, UNITED STATES OF AMERICA.,
    1. Year: 2025
    2. Date: May 01
    3. Epub Date: 2025 05 01
  2. Journal: Angewandte Chemie (International ed. in English)
    1. Pages: e202505971
  4. Type of Article: Article
  5. Article Number: e202505971
  1. Abstract:

    The challenge of targeting RNA with small molecules necessitates a better understanding of RNA-ligand interaction mechanisms. However, the dynamic nature of nucleic acids, their ligand-induced stabilization, and how conformational changes influence gene expression pose significant difficulties for experimental investigation. This work employs a combination of computational and experimental methods to address these challenges. By integrating structure-informed design, crystallography, and machine learning-augmented all atom molecular dynamics simulations (MD) we synthesized, biophysically and biochemically characterized, and studied the dissociation of a library of small molecule activators of the ZTP riboswitch, a ligand-binding RNA motif that regulates bacterial gene expression. We uncovered key interaction mechanisms, revealing valuable insights into the role of ligand binding kinetics on riboswitch activation. Further, we established that ligand on-rates determine activation potency as opposed to binding affinity and elucidated RNA structural differences, which provide mechanistic insights into the interplay of RNA structure on riboswitch activation. © 2025 Wiley-VCH GmbH.

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  2. DOI: 10.1002/anie.202505971
  3. PMID: 40310613

Library Notes

  1. Fiscal Year: FY2024-2025
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