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A synthetic peptide mimic kills Candida albicans and synergistically prevents infection

Author

Listed:
  • Sebastian Schaefer

    (University of New South Wales (UNSW)
    UNSW
    UNSW
    Hans Knoell Institute)

  • Raghav Vij

    (Hans Knoell Institute)

  • Jakob L. Sprague

    (Hans Knoell Institute)

  • Sophie Austermeier

    (Hans Knoell Institute)

  • Hue Dinh

    (Macquarie University)

  • Peter R. Judzewitsch

    (University of New South Wales (UNSW)
    UNSW)

  • Sven Müller-Loennies

    (Leibniz Lung Center)

  • Taynara Lopes Silva

    (Hans Knoell Institute)

  • Eric Seemann

    (Jena University Hospital – Friedrich Schiller University Jena)

  • Britta Qualmann

    (Jena University Hospital – Friedrich Schiller University Jena)

  • Christian Hertweck

    (Hans Knoell Institute
    Friedrich Schiller University Jena
    Friedrich Schiller University Jena)

  • Kirstin Scherlach

    (Hans Knoell Institute)

  • Thomas Gutsmann

    (Leibniz Lung Center
    Centre for Structural Systems Biology (CSSB))

  • Amy K. Cain

    (Macquarie University)

  • Nathaniel Corrigan

    (University of New South Wales (UNSW)
    UNSW)

  • Mark S. Gresnigt

    (Friedrich Schiller University Jena
    Hans Knoell Institute)

  • Cyrille Boyer

    (University of New South Wales (UNSW)
    UNSW)

  • Megan D. Lenardon

    (UNSW)

  • Sascha Brunke

    (Hans Knoell Institute)

Abstract

More than two million people worldwide are affected by life-threatening, invasive fungal infections annually. Candida species are the most common cause of nosocomial, invasive fungal infections and are associated with mortality rates above 40%. Despite the increasing incidence of drug-resistance, the development of novel antifungal formulations has been limited. Here we investigate the antifungal mode of action and therapeutic potential of positively charged, synthetic peptide mimics to combat Candida albicans infections. Our data indicates that these synthetic polymers cause endoplasmic reticulum stress and affect protein glycosylation, a mode of action distinct from currently approved antifungal drugs. The most promising polymer composition damaged the mannan layer of the cell wall, with additional membrane-disrupting activity. The synergistic combination of the polymer with caspofungin prevented infection of human epithelial cells in vitro, improved fungal clearance by human macrophages, and significantly increased host survival in a Galleria mellonella model of systemic candidiasis. Additionally, prolonged exposure of C. albicans to the synergistic combination of polymer and caspofungin did not lead to the evolution of tolerant strains in vitro. Together, this work highlights the enormous potential of these synthetic peptide mimics to be used as novel antifungal formulations as well as adjunctive antifungal therapy.

Suggested Citation

  • Sebastian Schaefer & Raghav Vij & Jakob L. Sprague & Sophie Austermeier & Hue Dinh & Peter R. Judzewitsch & Sven Müller-Loennies & Taynara Lopes Silva & Eric Seemann & Britta Qualmann & Christian Hert, 2024. "A synthetic peptide mimic kills Candida albicans and synergistically prevents infection," Nature Communications, Nature, vol. 15(1), pages 1-22, December.
    • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-50491-x
    DOI: 10.1038/s41467-024-50491-x
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    References listed on IDEAS

    as
    1. Zeileis, Achim & Grothendieck, Gabor, 2005. "zoo: S3 Infrastructure for Regular and Irregular Time Series," Journal of Statistical Software, Foundation for Open Access Statistics, vol. 14(i06).
    2. Nicole M. Revie & Kali R. Iyer & Michelle E. Maxson & Jiabao Zhang & Su Yan & Caroline M. Fernandes & Kirsten J. Meyer & Xuefei Chen & Iwona Skulska & Meea Fogal & Hiram Sanchez & Saif Hossain & Sheen, 2022. "Targeting fungal membrane homeostasis with imidazopyrazoindoles impairs azole resistance and biofilm formation," Nature Communications, Nature, vol. 13(1), pages 1-20, December.
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