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Differential interactions determine anisotropies at interfaces of RNA-based biomolecular condensates

Author

Listed:
  • Nadia A. Erkamp

    (University of Cambridge
    Washington University in St. Louis
    Eindhoven University of Technology)

  • Mina Farag

    (Washington University in St. Louis
    Washington University in St. Louis)

  • Yuanxin Qiu

    (Washington University in St. Louis
    Washington University in St. Louis)

  • Daoyuan Qian

    (University of Cambridge)

  • Tomas Sneideris

    (University of Cambridge)

  • Tingting Wu

    (Washington University in St. Louis)

  • Timothy J. Welsh

    (University of Cambridge)

  • Hannes Ausserwöger

    (University of Cambridge)

  • Tommy J. Krug

    (Harvard University)

  • Gaurav Chauhan

    (Washington University in St. Louis
    Washington University in St. Louis
    Indian Institute of Technology)

  • David A. Weitz

    (Harvard University
    Harvard University
    Harvard University)

  • Matthew D. Lew

    (Washington University in St. Louis
    Washington University in St. Louis)

  • Tuomas P. J. Knowles

    (University of Cambridge
    University of Cambridge)

  • Rohit V. Pappu

    (Washington University in St. Louis
    Washington University in St. Louis)

Abstract

Biomolecular condensates form via macromolecular phase separation. Here, we report results from our characterization of synthetic condensates formed by phase separation of mixtures comprising two types of RNA molecules and the biocompatible polymer polyethylene glycol. Purine-rich RNAs are scaffolds that drive phase separation via heterotypic interactions. Conversely, pyrimidine-rich RNA molecules are adsorbents defined by weaker heterotypic interactions. They adsorb onto and wet the interfaces of coexisting phases formed by scaffolds. Lattice-based simulations reproduce the phenomenology observed in experiments and these simulations predict that scaffolds and adsorbents have different non-random orientational preferences at interfaces. Dynamics at interfaces were probed using single-molecule tracking of fluorogenic probes bound to RNA molecules. These experiments revealed dynamical anisotropy at interfaces whereby motions of probe molecules parallel to the interface are faster than motions perpendicular to the interface. Taken together, our findings have broad implications for designing synthetic condensates with tunable interfacial properties.

Suggested Citation

  • Nadia A. Erkamp & Mina Farag & Yuanxin Qiu & Daoyuan Qian & Tomas Sneideris & Tingting Wu & Timothy J. Welsh & Hannes Ausserwöger & Tommy J. Krug & Gaurav Chauhan & David A. Weitz & Matthew D. Lew & T, 2025. "Differential interactions determine anisotropies at interfaces of RNA-based biomolecular condensates," Nature Communications, Nature, vol. 16(1), pages 1-13, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-58736-z
    DOI: 10.1038/s41467-025-58736-z
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    References listed on IDEAS

    as
    1. Gaurav Chauhan & Mina Farag & Samuel R. Cohen & Rohit V. Pappu, 2024. "Reply to: The conformations of protein chains at the interface of biomolecular condensates," Nature Communications, Nature, vol. 15(1), pages 1-4, December.
    2. Nadia A. Erkamp & Tomas Sneideris & Hannes Ausserwöger & Daoyuan Qian & Seema Qamar & Jonathon Nixon-Abell & Peter George-Hyslop & Jeremy D. Schmit & David A. Weitz & Tuomas P. J. Knowles, 2023. "Spatially non-uniform condensates emerge from dynamically arrested phase separation," Nature Communications, Nature, vol. 14(1), pages 1-8, December.
    3. Mina Farag & Wade M. Borcherds & Anne Bremer & Tanja Mittag & Rohit V. Pappu, 2023. "Phase separation of protein mixtures is driven by the interplay of homotypic and heterotypic interactions," Nature Communications, Nature, vol. 14(1), pages 1-16, December.
    4. William E. Arter & Runzhang Qi & Nadia A. Erkamp & Georg Krainer & Kieran Didi & Timothy J. Welsh & Julia Acker & Jonathan Nixon-Abell & Seema Qamar & Jordina Guillén-Boixet & Titus M. Franzmann & Dav, 2022. "Biomolecular condensate phase diagrams with a combinatorial microdroplet platform," Nature Communications, Nature, vol. 13(1), pages 1-10, December.
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