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Structure-based discovery of small molecules that disaggregate Alzheimer’s disease tissue derived tau fibrils in vitro

Author

Listed:
  • Paul M. Seidler

    (UCLA
    UCLA
    UCLA-DOE Institute
    UCLA)

  • Kevin A. Murray

    (UCLA
    UCLA
    UCLA-DOE Institute
    UCLA)

  • David R. Boyer

    (UCLA
    UCLA
    UCLA-DOE Institute
    UCLA)

  • Peng Ge

    (UCLA
    UCLA
    UCLA-DOE Institute
    UCLA)

  • Michael R. Sawaya

    (UCLA
    UCLA
    UCLA-DOE Institute
    UCLA)

  • Carolyn J. Hu

    (UCLA
    UCLA
    UCLA-DOE Institute
    UCLA)

  • Xinyi Cheng

    (UCLA
    UCLA
    UCLA-DOE Institute
    UCLA)

  • Romany Abskharon

    (UCLA
    UCLA
    UCLA-DOE Institute
    UCLA)

  • Hope Pan

    (UCLA
    UCLA
    UCLA-DOE Institute
    UCLA)

  • Michael A. DeTure

    (Mayo Clinic)

  • Christopher K. Williams

    (David Geffen School of Medicine, UCLA)

  • Dennis W. Dickson

    (Mayo Clinic)

  • Harry V. Vinters

    (David Geffen School of Medicine, UCLA
    David Geffen School of Medicine, UCLA)

  • David S. Eisenberg

    (UCLA
    UCLA
    UCLA-DOE Institute
    UCLA)

Abstract

Alzheimer’s disease (AD) is the consequence of neuronal death and brain atrophy associated with the aggregation of protein tau into fibrils. Thus disaggregation of tau fibrils could be a therapeutic approach to AD. The small molecule EGCG, abundant in green tea, has long been known to disaggregate tau and other amyloid fibrils, but EGCG has poor drug-like properties, failing to fully penetrate the brain. Here we have cryogenically trapped an intermediate of brain-extracted tau fibrils on the kinetic pathway to EGCG-induced disaggregation and have determined its cryoEM structure. The structure reveals that EGCG molecules stack in polar clefts between the paired helical protofilaments that pathologically define AD. Treating the EGCG binding position as a pharmacophore, we computationally screened thousands of drug-like compounds for compatibility for the pharmacophore, discovering several that experimentally disaggregate brain-derived tau fibrils in vitro. This work suggests the potential of structure-based, small-molecule drug discovery for amyloid diseases.

Suggested Citation

  • Paul M. Seidler & Kevin A. Murray & David R. Boyer & Peng Ge & Michael R. Sawaya & Carolyn J. Hu & Xinyi Cheng & Romany Abskharon & Hope Pan & Michael A. DeTure & Christopher K. Williams & Dennis W. D, 2022. "Structure-based discovery of small molecules that disaggregate Alzheimer’s disease tissue derived tau fibrils in vitro," Nature Communications, Nature, vol. 13(1), pages 1-12, December.
  • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-32951-4
    DOI: 10.1038/s41467-022-32951-4
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    Cited by:

    1. Gregory E. Merz & Matthew J. Chalkley & Sophia K. Tan & Eric Tse & Joanne Lee & Stanley B. Prusiner & Nick A. Paras & William F. DeGrado & Daniel R. Southworth, 2023. "Stacked binding of a PET ligand to Alzheimer’s tau paired helical filaments," Nature Communications, Nature, vol. 14(1), pages 1-11, December.
    2. Dilraj Lama & Thibault Vosselman & Cagla Sahin & Judit Liaño-Pons & Carmine P. Cerrato & Lennart Nilsson & Kaare Teilum & David P. Lane & Michael Landreh & Marie Arsenian Henriksson, 2024. "A druggable conformational switch in the c-MYC transactivation domain," Nature Communications, Nature, vol. 15(1), pages 1-14, December.
    3. Peter Kunach & Jaime Vaquer-Alicea & Matthew S. Smith & Jim Monistrol & Robert Hopewell & Luc Moquin & Joseph Therriault & Cecile Tissot & Nesrine Rahmouni & Gassan Massarweh & Jean-Paul Soucy & Marie, 2024. "Cryo-EM structure of Alzheimer’s disease tau filaments with PET ligand MK-6240," Nature Communications, Nature, vol. 15(1), pages 1-7, December.

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