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Molecular basis of an agarose metabolic pathway acquired by a human intestinal symbiont

Author

Listed:
  • Benjamin Pluvinage

    (University of Victoria)

  • Julie M. Grondin

    (Lethbridge Research and Development Centre)

  • Carolyn Amundsen

    (Lethbridge Research and Development Centre)

  • Leeann Klassen

    (Lethbridge Research and Development Centre)

  • Paul E. Moote

    (Lethbridge Research and Development Centre
    University of Alberta)

  • Yao Xiao

    (University of Michigan Medical School)

  • Dallas Thomas

    (Lethbridge Research and Development Centre)

  • Nicholas A. Pudlo

    (University of Michigan Medical School)

  • Anuoluwapo Anele

    (Lethbridge Research and Development Centre)

  • Eric C. Martens

    (University of Michigan Medical School)

  • G. Douglas Inglis

    (Lethbridge Research and Development Centre
    University of Alberta)

  • Richard E. R. Uwiera

    (University of Alberta)

  • Alisdair B. Boraston

    (University of Victoria)

  • D. Wade Abbott

    (Lethbridge Research and Development Centre)

Abstract

In red algae, the most abundant principal cell wall polysaccharides are mixed galactan agars, of which agarose is a common component. While bioconversion of agarose is predominantly catalyzed by bacteria that live in the oceans, agarases have been discovered in microorganisms that inhabit diverse terrestrial ecosystems, including human intestines. Here we comprehensively define the structure–function relationship of the agarolytic pathway from the human intestinal bacterium Bacteroides uniformis (Bu) NP1. Using recombinant agarases from Bu NP1 to completely depolymerize agarose, we demonstrate that a non-agarolytic Bu strain can grow on GAL released from agarose. This relationship underscores that rare nutrient utilization by intestinal bacteria is facilitated by the acquisition of highly specific enzymes that unlock inaccessible carbohydrate resources contained within unusual polysaccharides. Intriguingly, the agarolytic pathway is differentially distributed throughout geographically distinct human microbiomes, reflecting a complex historical context for agarose consumption by human beings.

Suggested Citation

  • Benjamin Pluvinage & Julie M. Grondin & Carolyn Amundsen & Leeann Klassen & Paul E. Moote & Yao Xiao & Dallas Thomas & Nicholas A. Pudlo & Anuoluwapo Anele & Eric C. Martens & G. Douglas Inglis & Rich, 2018. "Molecular basis of an agarose metabolic pathway acquired by a human intestinal symbiont," Nature Communications, Nature, vol. 9(1), pages 1-14, December.
    • Handle: RePEc:nat:natcom:v:9:y:2018:i:1:d:10.1038_s41467-018-03366-x
    DOI: 10.1038/s41467-018-03366-x
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    Cited by:

    1. Carla Pérez-Cruz & Alicia Moraleda-Montoya & Raquel Liébana & Oihana Terrones & Uxue Arrizabalaga & Mikel García-Alija & Maier Lorizate & Ana Martínez Gascueña & Isabel García-Álvarez & Jon Ander Niet, 2024. "Mechanisms of recalcitrant fucoidan breakdown in marine Planctomycetota," Nature Communications, Nature, vol. 15(1), pages 1-24, December.

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