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De novo designed proteins neutralize lethal snake venom toxins

Research output: Contribution to Journal/MagazineJournal articlepeer-review

E-pub ahead of print
  • Susana Vázquez Torres
  • Melisa Benard Valle
  • Stephen P. Mackessy
  • Nicholas R. Casewell
  • Shirin Ahmadi
  • Nick J. Burlet
  • Edin Muratspahić
  • Isaac Sappington
  • Max D. Overath
  • Esperanza Rivera-de-Torre
  • Jann Ledergerber
  • Andreas H. Laustsen
  • Kim Boddum
  • Asim K. Bera
  • Alex Kang
  • Evans Brackenbrough
  • Iara A. Cardoso
  • Edouard P. Crittenden
  • Rebecca J. Edge
  • Justin Decarreau
  • Robert J. Ragotte
  • Arvind S. Pillai
  • Mohamad Abedi
  • Hannah L. Han
  • Stacey R. Gerben
  • Analisa Murray
  • Rebecca Skotheim
  • Lynda Stuart
  • Lance Stewart
  • Thomas J. A. Fryer
  • Timothy P. Jenkins
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<mark>Journal publication date</mark>15/01/2025
<mark>Journal</mark>Nature
Publication StatusE-pub ahead of print
Early online date15/01/25
<mark>Original language</mark>English

Abstract

Snakebite envenoming remains a devastating and neglected tropical disease, claiming over 100,000 lives annually and causing severe complications and long-lasting disabilities for many more1,2. Three-finger toxins (3FTx) are highly toxic components of elapid snake venoms that can cause diverse pathologies, including severe tissue damage3 and inhibition of nicotinic acetylcholine receptors, resulting in life-threatening neurotoxicity4. At present, the only available treatments for snakebites consist of polyclonal antibodies derived from the plasma of immunized animals, which have high cost and limited efficacy against 3FTxs5–7. Here we used deep learning methods to de novo design proteins to bind short-chain and long-chain α-neurotoxins and cytotoxins from the 3FTx family. With limited experimental screening, we obtained protein designs with remarkable thermal stability, high binding affinity and near-atomic-level agreement with the computational models. The designed proteins effectively neutralized all three 3FTx subfamilies in vitro and protected mice from a lethal neurotoxin challenge. Such potent, stable and readily manufacturable toxin-neutralizing proteins could provide the basis for safer, cost-effective and widely accessible next-generation antivenom therapeutics. Beyond snakebite, our results highlight how computational design could help democratize therapeutic discovery, particularly in resource-limited settings, by substantially reducing costs and resource requirements for the development of therapies for neglected tropical diseases.