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A self-assembled protein β-helix as a self-contained biofunctional motif

Author

Listed:
  • Camilla Dondi

    (National Physical Laboratory
    University College London)

  • Javier Garcia-Ruiz

    (National Physical Laboratory
    King’s College London)

  • Erol Hasan

    (National Physical Laboratory
    King Abdullah University of Science and Technology)

  • Stephanie Rey

    (National Physical Laboratory)

  • James E. Noble

    (National Physical Laboratory)

  • Alex Hoose

    (National Physical Laboratory)

  • Andrea Briones

    (National Physical Laboratory)

  • Ibolya E. Kepiro

    (National Physical Laboratory)

  • Nilofar Faruqui

    (National Physical Laboratory)

  • Purnank Aggarwal

    (National Physical Laboratory)

  • Poonam Ghai

    (National Physical Laboratory)

  • Michael Shaw

    (National Physical Laboratory
    University College London)

  • Antony T. Fry

    (National Physical Laboratory)

  • Antony Maxwell

    (National Physical Laboratory)

  • Bart W. Hoogenboom

    (University College London
    University College London)

  • Christian D. Lorenz

    (King’s College London)

  • Maxim G. Ryadnov

    (National Physical Laboratory
    King’s College London)

Abstract

Nature constructs matter by employing protein folding motifs, many of which have been synthetically reconstituted to exploit function. A less understood motif whose structure-function relationships remain unexploited is formed by parallel β-strands arranged in a helical repetitive pattern, termed a β-helix. Herein we reconstitute a protein β-helix by design and endow it with biological function. Unlike β-helical proteins, which are contiguous covalent structures, this β-helix self-assembles from an elementary sequence of 18 amino acids. Using a combination of experimental and computational methods, we demonstrate that the resulting assemblies are discrete cylindrical structures exhibiting conserved dimensions at the nanoscale. We provide evidence for the structures to form a carpet-like three-dimensional scaffold promoting and inhibiting the growth of human and bacterial cells, respectively, while being able to mediate intracellular gene delivery. The study introduces a self-assembled β-helix as a self-contained bio- and multi-functional motif for exploring and exploiting mechanistic biology.

Suggested Citation

  • Camilla Dondi & Javier Garcia-Ruiz & Erol Hasan & Stephanie Rey & James E. Noble & Alex Hoose & Andrea Briones & Ibolya E. Kepiro & Nilofar Faruqui & Purnank Aggarwal & Poonam Ghai & Michael Shaw & An, 2025. "A self-assembled protein β-helix as a self-contained biofunctional motif," Nature Communications, Nature, vol. 16(1), pages 1-18, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-59873-1
    DOI: 10.1038/s41467-025-59873-1
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    References listed on IDEAS

    as
    1. Ovijit Chaudhuri & Justin Cooper-White & Paul A. Janmey & David J. Mooney & Vivek B. Shenoy, 2020. "Effects of extracellular matrix viscoelasticity on cellular behaviour," Nature, Nature, vol. 584(7822), pages 535-546, August.
    2. Emiliana Santis & Hasan Alkassem & Baptiste Lamarre & Nilofar Faruqui & Angelo Bella & James E. Noble & Nicola Micale & Santanu Ray & Jonathan R. Burns & Alexander R. Yon & Bart W. Hoogenboom & Maxim , 2017. "Antimicrobial peptide capsids of de novo design," Nature Communications, Nature, vol. 8(1), pages 1-11, December.
    3. Yih-Cherng Liou & Ante Tocilj & Peter L. Davies & Zongchao Jia, 2000. "Mimicry of ice structure by surface hydroxyls and water of a β-helix antifreeze protein," Nature, Nature, vol. 406(6793), pages 322-324, July.
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