Molecular basis of an agarose metabolic pathway acquired by a human intestinal symbiont
Polysaccharides are the primary structural cell wall and energy storage molecules of seaweed. Here, the authors show how the geographically restricted dietary polysaccharide agarose is selectively utilized by the human intestinal bacterium Bacteroides uniformis, providing insight into how carbohydra...
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Nature Portfolio
2018
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oai:doaj.org-article:6a06d57a248e4054b87237b64ca061fd2021-12-02T17:33:04ZMolecular basis of an agarose metabolic pathway acquired by a human intestinal symbiont10.1038/s41467-018-03366-x2041-1723https://doaj.org/article/6a06d57a248e4054b87237b64ca061fd2018-03-01T00:00:00Zhttps://doi.org/10.1038/s41467-018-03366-xhttps://doaj.org/toc/2041-1723Polysaccharides are the primary structural cell wall and energy storage molecules of seaweed. Here, the authors show how the geographically restricted dietary polysaccharide agarose is selectively utilized by the human intestinal bacterium Bacteroides uniformis, providing insight into how carbohydrate metabolism evolves within the human microbiome.Benjamin PluvinageJulie M. GrondinCarolyn AmundsenLeeann KlassenPaul E. MooteYao XiaoDallas ThomasNicholas A. PudloAnuoluwapo AneleEric C. MartensG. Douglas InglisRichard E. R. UwieraAlisdair B. BorastonD. Wade AbbottNature PortfolioarticleScienceQENNature Communications, Vol 9, Iss 1, Pp 1-14 (2018) |
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Science Q |
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Science Q 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 Richard E. R. Uwiera Alisdair B. Boraston D. Wade Abbott Molecular basis of an agarose metabolic pathway acquired by a human intestinal symbiont |
description |
Polysaccharides are the primary structural cell wall and energy storage molecules of seaweed. Here, the authors show how the geographically restricted dietary polysaccharide agarose is selectively utilized by the human intestinal bacterium Bacteroides uniformis, providing insight into how carbohydrate metabolism evolves within the human microbiome. |
format |
article |
author |
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 Richard E. R. Uwiera Alisdair B. Boraston D. Wade Abbott |
author_facet |
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 Richard E. R. Uwiera Alisdair B. Boraston D. Wade Abbott |
author_sort |
Benjamin Pluvinage |
title |
Molecular basis of an agarose metabolic pathway acquired by a human intestinal symbiont |
title_short |
Molecular basis of an agarose metabolic pathway acquired by a human intestinal symbiont |
title_full |
Molecular basis of an agarose metabolic pathway acquired by a human intestinal symbiont |
title_fullStr |
Molecular basis of an agarose metabolic pathway acquired by a human intestinal symbiont |
title_full_unstemmed |
Molecular basis of an agarose metabolic pathway acquired by a human intestinal symbiont |
title_sort |
molecular basis of an agarose metabolic pathway acquired by a human intestinal symbiont |
publisher |
Nature Portfolio |
publishDate |
2018 |
url |
https://doaj.org/article/6a06d57a248e4054b87237b64ca061fd |
work_keys_str_mv |
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