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Synthetic group A streptogramin antibiotics that overcome Vat resistance

Author

Listed:
  • Qi Li

    (University of California, San Francisco)

  • Jenna Pellegrino

    (University of California, San Francisco)

  • D. John Lee

    (University of California, San Francisco)

  • Arthur A. Tran

    (University of California, San Francisco)

  • Hector A. Chaires

    (University of California, San Francisco)

  • Ruoxi Wang

    (University of California, San Francisco)

  • Jesslyn E. Park

    (University of California, San Francisco)

  • Kaijie Ji

    (University of California, San Francisco)

  • David Chow

    (University of California, San Francisco)

  • Na Zhang

    (University of California, San Francisco
    Beijing University of Technology)

  • Axel F. Brilot

    (University of California, San Francisco)

  • Justin T. Biel

    (University of California, San Francisco)

  • Gydo Zundert

    (Schrödinger)

  • Kenneth Borrelli

    (University of California, San Francisco)

  • Dean Shinabarger

    (Micromyx)

  • Cindy Wolfe

    (Micromyx)

  • Beverly Murray

    (Micromyx)

  • Matthew P. Jacobson

    (University of California, San Francisco)

  • Estelle Mühle

    (Institut Pasteur)

  • Olivier Chesneau

    (Institut Pasteur)

  • James S. Fraser

    (University of California, San Francisco)

  • Ian B. Seiple

    (University of California, San Francisco)

Abstract

Natural products serve as chemical blueprints for most antibiotics in clinical use. The evolutionary process by which these molecules arise is inherently accompanied by the co-evolution of resistance mechanisms that shorten the clinical lifetime of any given class of antibiotics1. Virginiamycin acetyltransferase (Vat) enzymes are resistance proteins that provide protection against streptogramins2, potent antibiotics against Gram-positive bacteria that inhibit the bacterial ribosome3. Owing to the challenge of selectively modifying the chemically complex, 23-membered macrocyclic scaffold of group A streptogramins, analogues that overcome the resistance conferred by Vat enzymes have not been previously developed2. Here we report the design, synthesis, and antibacterial evaluation of group A streptogramin antibiotics with extensive structural variability. Using cryo-electron microscopy and forcefield-based refinement, we characterize the binding of eight analogues to the bacterial ribosome at high resolution, revealing binding interactions that extend into the peptidyl tRNA-binding site and towards synergistic binders that occupy the nascent peptide exit tunnel. One of these analogues has excellent activity against several streptogramin-resistant strains of Staphylococcus aureus, exhibits decreased rates of acetylation in vitro, and is effective at lowering bacterial load in a mouse model of infection. Our results demonstrate that the combination of rational design and modular chemical synthesis can revitalize classes of antibiotics that are limited by naturally arising resistance mechanisms.

Suggested Citation

  • Qi Li & Jenna Pellegrino & D. John Lee & Arthur A. Tran & Hector A. Chaires & Ruoxi Wang & Jesslyn E. Park & Kaijie Ji & David Chow & Na Zhang & Axel F. Brilot & Justin T. Biel & Gydo Zundert & Kennet, 2020. "Synthetic group A streptogramin antibiotics that overcome Vat resistance," Nature, Nature, vol. 586(7827), pages 145-150, October.
    • Handle: RePEc:nat:nature:v:586:y:2020:i:7827:d:10.1038_s41586-020-2761-3
    DOI: 10.1038/s41586-020-2761-3
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    Cited by:

    1. Chih-Wei Chen & Nadja Leimer & Egor A. Syroegin & Clémence Dunand & Zackery P. Bulman & Kim Lewis & Yury S. Polikanov & Maxim S. Svetlov, 2023. "Structural insights into the mechanism of overcoming Erm-mediated resistance by macrolides acting together with hygromycin-A," Nature Communications, Nature, vol. 14(1), pages 1-13, December.
    2. Meenakshi Venkatesan & Michael Fruci & Lou Ann Verellen & Tatiana Skarina & Nathalie Mesa & Robert Flick & Chester Pham & Radhakrishnan Mahadevan & Peter J. Stogios & Alexei Savchenko, 2023. "Molecular mechanism of plasmid-borne resistance to sulfonamide antibiotics," Nature Communications, Nature, vol. 14(1), pages 1-17, December.
    3. Christopher J. Barden & Fan Wu & J. Pedro Fernandez-Murray & Erhu Lu & Shengguo Sun & Marcia M. Taylor & Annette L. Rushton & Jason Williams & Mahtab Tavasoli & Autumn Meek & Alla Siva Reddy & Lisa M., 2024. "Computer-aided drug design to generate a unique antibiotic family," Nature Communications, Nature, vol. 15(1), pages 1-10, December.

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