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Diversity oriented biosynthesis via accelerated evolution of modular gene clusters

Author

Listed:
  • Aleksandra Wlodek

    (Isomerase Therapeutics Ltd., Chesterford Research Park)

  • Steve G. Kendrew

    (Biotica Technology Ltd., Chesterford Research Park
    Engineered Biodesign Limited)

  • Nigel J. Coates

    (Isomerase Therapeutics Ltd., Chesterford Research Park
    Biotica Technology Ltd., Chesterford Research Park)

  • Adam Hold

    (Isomerase Therapeutics Ltd., Chesterford Research Park)

  • Joanna Pogwizd

    (Isomerase Therapeutics Ltd., Chesterford Research Park)

  • Steven Rudder

    (Isomerase Therapeutics Ltd., Chesterford Research Park)

  • Lesley S. Sheehan

    (Isomerase Therapeutics Ltd., Chesterford Research Park
    Biotica Technology Ltd., Chesterford Research Park)

  • Sarah J. Higginbotham

    (Isomerase Therapeutics Ltd., Chesterford Research Park)

  • Anna E. Stanley-Smith

    (Isomerase Therapeutics Ltd., Chesterford Research Park
    Biotica Technology Ltd., Chesterford Research Park)

  • Tony Warneck

    (Biotica Technology Ltd., Chesterford Research Park)

  • Mohammad Nur-E-Alam

    (Biotica Technology Ltd., Chesterford Research Park
    King Saud University)

  • Markus Radzom

    (Biotica Technology Ltd., Chesterford Research Park
    BASF SE)

  • Christine J. Martin

    (Biotica Technology Ltd., Chesterford Research Park)

  • Lois Overvoorde

    (Isomerase Therapeutics Ltd., Chesterford Research Park)

  • Markiyan Samborskyy

    (University of Cambridge)

  • Silke Alt

    (John Innes Centre, Norwich Research Park)

  • Daniel Heine

    (John Innes Centre, Norwich Research Park)

  • Guy T. Carter

    (Wyeth Pharmaceuticals)

  • Edmund I. Graziani

    (Wyeth Pharmaceuticals
    Medicine Discovery Network-Synthetic Biology, Pfizer Worldwide R&D)

  • Frank E. Koehn

    (Wyeth Pharmaceuticals)

  • Leonard McDonald

    (Wyeth Pharmaceuticals)

  • Alexander Alanine

    (Pharmaceutical Research and Early Development (PRED))

  • Rosa María Rodríguez Sarmiento

    (Pharmaceutical Research and Early Development (PRED))

  • Suzan Keen Chao

    (Pharmaceutical Research and Early Development (PRED))

  • Hasane Ratni

    (Pharmaceutical Research and Early Development (PRED))

  • Lucinda Steward

    (Pharmaceutical Research and Early Development (PRED))

  • Isobel H. Norville

    (Defence Science and Technology Laboratory)

  • Mitali Sarkar-Tyson

    (Defence Science and Technology Laboratory
    University of Western Australia)

  • Steven J. Moss

    (Isomerase Therapeutics Ltd., Chesterford Research Park
    Biotica Technology Ltd., Chesterford Research Park)

  • Peter F. Leadlay

    (University of Cambridge)

  • Barrie Wilkinson

    (Isomerase Therapeutics Ltd., Chesterford Research Park
    Biotica Technology Ltd., Chesterford Research Park
    John Innes Centre, Norwich Research Park)

  • Matthew A. Gregory

    (Isomerase Therapeutics Ltd., Chesterford Research Park
    Biotica Technology Ltd., Chesterford Research Park)

Abstract

Erythromycin, avermectin and rapamycin are clinically useful polyketide natural products produced on modular polyketide synthase multienzymes by an assembly-line process in which each module of enzymes in turn specifies attachment of a particular chemical unit. Although polyketide synthase encoding genes have been successfully engineered to produce novel analogues, the process can be relatively slow, inefficient, and frequently low-yielding. We now describe a method for rapidly recombining polyketide synthase gene clusters to replace, add or remove modules that, with high frequency, generates diverse and highly productive assembly lines. The method is exemplified in the rapamycin biosynthetic gene cluster where, in a single experiment, multiple strains were isolated producing new members of a rapamycin-related family of polyketides. The process mimics, but significantly accelerates, a plausible mechanism of natural evolution for modular polyketide synthases. Detailed sequence analysis of the recombinant genes provides unique insight into the design principles for constructing useful synthetic assembly-line multienzymes.

Suggested Citation

  • Aleksandra Wlodek & Steve G. Kendrew & Nigel J. Coates & Adam Hold & Joanna Pogwizd & Steven Rudder & Lesley S. Sheehan & Sarah J. Higginbotham & Anna E. Stanley-Smith & Tony Warneck & Mohammad Nur-E-, 2017. "Diversity oriented biosynthesis via accelerated evolution of modular gene clusters," Nature Communications, Nature, vol. 8(1), pages 1-10, December.
    • Handle: RePEc:nat:natcom:v:8:y:2017:i:1:d:10.1038_s41467-017-01344-3
    DOI: 10.1038/s41467-017-01344-3
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    Cited by:

    1. Elias Englund & Matthias Schmidt & Alberto A. Nava & Sarah Klass & Leah Keiser & Qingyun Dan & Leonard Katz & Satoshi Yuzawa & Jay D. Keasling, 2023. "Biosensor Guided Polyketide Synthases Engineering for Optimization of Domain Exchange Boundaries," Nature Communications, Nature, vol. 14(1), pages 1-12, December.
    2. Thomas J. Booth & Kenan A. J. Bozhüyük & Jonathon D. Liston & Sibyl F. D. Batey & Ernest Lacey & Barrie Wilkinson, 2022. "Bifurcation drives the evolution of assembly-line biosynthesis," Nature Communications, Nature, vol. 13(1), pages 1-12, December.
    3. Guifa Zhai & Yan Zhu & Guo Sun & Fan Zhou & Yangning Sun & Zhou Hong & Chuan Dong & Peter F. Leadlay & Kui Hong & Zixin Deng & Fuling Zhou & Yuhui Sun, 2023. "Insights into azalomycin F assembly-line contribute to evolution-guided polyketide synthase engineering and identification of intermodular recognition," Nature Communications, Nature, vol. 14(1), pages 1-12, December.

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