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Comprehensive prediction of secondary metabolite structure and biological activity from microbial genome sequences

Author

Listed:
  • Michael A. Skinnider

    (McMaster University
    McMaster University
    Adapsyn Bioscience
    University of British Columbia)

  • Chad W. Johnston

    (McMaster University
    McMaster University
    Adapsyn Bioscience
    Massachusetts Institute of Technology)

  • Mathusan Gunabalasingam

    (McMaster University
    McMaster University)

  • Nishanth J. Merwin

    (McMaster University
    McMaster University)

  • Agata M. Kieliszek

    (Adapsyn Bioscience)

  • Robyn J. MacLellan

    (Adapsyn Bioscience)

  • Haoxin Li

    (Adapsyn Bioscience)

  • Michael R. M. Ranieri

    (McMaster University
    McMaster University)

  • Andrew L. H. Webster

    (McMaster University
    McMaster University)

  • My P. T. Cao

    (McMaster University
    McMaster University)

  • Annabelle Pfeifle

    (Adapsyn Bioscience)

  • Norman Spencer

    (Adapsyn Bioscience)

  • Q. Huy To

    (McMaster University
    McMaster University)

  • Dan Peter Wallace

    (Adapsyn Bioscience)

  • Chris A. Dejong

    (Adapsyn Bioscience)

  • Nathan A. Magarvey

    (McMaster University
    McMaster University)

Abstract

Novel antibiotics are urgently needed to address the looming global crisis of antibiotic resistance. Historically, the primary source of clinically used antibiotics has been microbial secondary metabolism. Microbial genome sequencing has revealed a plethora of uncharacterized natural antibiotics that remain to be discovered. However, the isolation of these molecules is hindered by the challenge of linking sequence information to the chemical structures of the encoded molecules. Here, we present PRISM 4, a comprehensive platform for prediction of the chemical structures of genomically encoded antibiotics, including all classes of bacterial antibiotics currently in clinical use. The accuracy of chemical structure prediction enables the development of machine-learning methods to predict the likely biological activity of encoded molecules. We apply PRISM 4 to chart secondary metabolite biosynthesis in a collection of over 10,000 bacterial genomes from both cultured isolates and metagenomic datasets, revealing thousands of encoded antibiotics. PRISM 4 is freely available as an interactive web application at http://prism.adapsyn.com .

Suggested Citation

  • Michael A. Skinnider & Chad W. Johnston & Mathusan Gunabalasingam & Nishanth J. Merwin & Agata M. Kieliszek & Robyn J. MacLellan & Haoxin Li & Michael R. M. Ranieri & Andrew L. H. Webster & My P. T. C, 2020. "Comprehensive prediction of secondary metabolite structure and biological activity from microbial genome sequences," Nature Communications, Nature, vol. 11(1), pages 1-9, December.
  • Handle: RePEc:nat:natcom:v:11:y:2020:i:1:d:10.1038_s41467-020-19986-1
    DOI: 10.1038/s41467-020-19986-1
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    Cited by:

    1. Yi-Yuan Lee & Mustafa Guler & Desnor N. Chigumba & Shen Wang & Neel Mittal & Cameron Miller & Benjamin Krummenacher & Haodong Liu & Liu Cao & Aditya Kannan & Keshav Narayan & Samuel T. Slocum & Bryan , 2023. "HypoRiPPAtlas as an Atlas of hypothetical natural products for mass spectrometry database search," Nature Communications, Nature, vol. 14(1), pages 1-17, December.
    2. Gita Naseri, 2023. "A roadmap to establish a comprehensive platform for sustainable manufacturing of natural products in yeast," Nature Communications, Nature, vol. 14(1), pages 1-13, December.
    3. Donghui Yan & Muqing Zhou & Abhinav Adduri & Yihao Zhuang & Mustafa Guler & Sitong Liu & Hyonyoung Shin & Torin Kovach & Gloria Oh & Xiao Liu & Yuting Deng & Xiaofeng Wang & Liu Cao & David H. Sherman, 2024. "Discovering type I cis-AT polyketides through computational mass spectrometry and genome mining with Seq2PKS," Nature Communications, Nature, vol. 15(1), pages 1-15, December.

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