Commensal bacteria make GPCR ligands that mimic human signalling molecules

Louis J. Cohen; Daria Esterhazy; Seong Hwan Kim; Christophe Lemetre; Rhiannon R. Aguilar; Emma A. Gordon; Amanda J. Pickard; Justin R. Cross; Ana B. Emiliano; Sun M. Han; John Chu; Xavier Vila-Farres; Jeremy Kaplitt; Aneta Rogoz; Paula Y. Calle; Craig Hunter; J. Kipchirchir Bitok; Sean F. Brady

doi:10.1038/nature23874

Commensal bacteria make GPCR ligands that mimic human signalling molecules

Louis J. Cohen
, Daria Esterhazy
, Seong Hwan Kim
, Christophe Lemetre
, Rhiannon R. Aguilar
, Emma A. Gordon
, Amanda J. Pickard
, Justin R. Cross
, Ana B. Emiliano
, Sun M. Han
, John Chu
, Xavier Vila-Farres
, Jeremy Kaplitt
, Aneta Rogoz
, Paula Y. Calle
, Craig Hunter
, J. Kipchirchir Bitok
, Sean F. Brady

Research output: Contribution to journal › Article › peer-review

406 Scopus citations

Abstract

Commensal bacteria are believed to have important roles in human health. The mechanisms by which they affect mammalian physiology remain poorly understood, but bacterial metabolites are likely to be key components of host interactions. Here we use bioinformatics and synthetic biology to mine the human microbiota for N-acyl amides that interact with G-protein-coupled receptors (GPCRs). We found that N-acyl amide synthase genes are enriched in gastrointestinal bacteria and the lipids that they encode interact with GPCRs that regulate gastrointestinal tract physiology. Mouse and cell-based models demonstrate that commensal GPR119 agonists regulate metabolic hormones and glucose homeostasis as efficiently as human ligands, although future studies are needed to define their potential physiological role in humans. Our results suggest that chemical mimicry of eukaryotic signalling molecules may be common among commensal bacteria and that manipulation of microbiota genes encoding metabolites that elicit host cellular responses represents a possible small-molecule therapeutic modality (microbiome-biosynthetic gene therapy).

Original language	English
Pages (from-to)	48-53
Number of pages	6
Journal	Nature
Volume	549
Issue number	7670
DOIs	https://doi.org/10.1038/nature23874
State	Published - 7 Sep 2017

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Cohen, L. J., Esterhazy, D., Kim, S. H., Lemetre, C., Aguilar, R. R., Gordon, E. A., Pickard, A. J., Cross, J. R., Emiliano, A. B., Han, S. M., Chu, J., Vila-Farres, X., Kaplitt, J., Rogoz, A., Calle, P. Y., Hunter, C., Bitok, J. K., & Brady, S. F. (2017). Commensal bacteria make GPCR ligands that mimic human signalling molecules. Nature, 549(7670), 48-53. https://doi.org/10.1038/nature23874

@article{d81758dc587546e9b0bb0a809a7ab9c7,

title = "Commensal bacteria make GPCR ligands that mimic human signalling molecules",

abstract = "Commensal bacteria are believed to have important roles in human health. The mechanisms by which they affect mammalian physiology remain poorly understood, but bacterial metabolites are likely to be key components of host interactions. Here we use bioinformatics and synthetic biology to mine the human microbiota for N-acyl amides that interact with G-protein-coupled receptors (GPCRs). We found that N-acyl amide synthase genes are enriched in gastrointestinal bacteria and the lipids that they encode interact with GPCRs that regulate gastrointestinal tract physiology. Mouse and cell-based models demonstrate that commensal GPR119 agonists regulate metabolic hormones and glucose homeostasis as efficiently as human ligands, although future studies are needed to define their potential physiological role in humans. Our results suggest that chemical mimicry of eukaryotic signalling molecules may be common among commensal bacteria and that manipulation of microbiota genes encoding metabolites that elicit host cellular responses represents a possible small-molecule therapeutic modality (microbiome-biosynthetic gene therapy).",

author = "Cohen, \{Louis J.\} and Daria Esterhazy and Kim, \{Seong Hwan\} and Christophe Lemetre and Aguilar, \{Rhiannon R.\} and Gordon, \{Emma A.\} and Pickard, \{Amanda J.\} and Cross, \{Justin R.\} and Emiliano, \{Ana B.\} and Han, \{Sun M.\} and John Chu and Xavier Vila-Farres and Jeremy Kaplitt and Aneta Rogoz and Calle, \{Paula Y.\} and Craig Hunter and Bitok, \{J. Kipchirchir\} and Brady, \{Sean F.\}",

year = "2017",

month = sep,

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doi = "10.1038/nature23874",

language = "English",

volume = "549",

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T1 - Commensal bacteria make GPCR ligands that mimic human signalling molecules

AU - Cohen, Louis J.

AU - Esterhazy, Daria

AU - Kim, Seong Hwan

AU - Lemetre, Christophe

AU - Aguilar, Rhiannon R.

AU - Gordon, Emma A.

AU - Pickard, Amanda J.

AU - Cross, Justin R.

AU - Emiliano, Ana B.

AU - Han, Sun M.

AU - Chu, John

AU - Vila-Farres, Xavier

AU - Kaplitt, Jeremy

AU - Rogoz, Aneta

AU - Calle, Paula Y.

AU - Hunter, Craig

AU - Bitok, J. Kipchirchir

AU - Brady, Sean F.

PY - 2017/9/7

Y1 - 2017/9/7

N2 - Commensal bacteria are believed to have important roles in human health. The mechanisms by which they affect mammalian physiology remain poorly understood, but bacterial metabolites are likely to be key components of host interactions. Here we use bioinformatics and synthetic biology to mine the human microbiota for N-acyl amides that interact with G-protein-coupled receptors (GPCRs). We found that N-acyl amide synthase genes are enriched in gastrointestinal bacteria and the lipids that they encode interact with GPCRs that regulate gastrointestinal tract physiology. Mouse and cell-based models demonstrate that commensal GPR119 agonists regulate metabolic hormones and glucose homeostasis as efficiently as human ligands, although future studies are needed to define their potential physiological role in humans. Our results suggest that chemical mimicry of eukaryotic signalling molecules may be common among commensal bacteria and that manipulation of microbiota genes encoding metabolites that elicit host cellular responses represents a possible small-molecule therapeutic modality (microbiome-biosynthetic gene therapy).

AB - Commensal bacteria are believed to have important roles in human health. The mechanisms by which they affect mammalian physiology remain poorly understood, but bacterial metabolites are likely to be key components of host interactions. Here we use bioinformatics and synthetic biology to mine the human microbiota for N-acyl amides that interact with G-protein-coupled receptors (GPCRs). We found that N-acyl amide synthase genes are enriched in gastrointestinal bacteria and the lipids that they encode interact with GPCRs that regulate gastrointestinal tract physiology. Mouse and cell-based models demonstrate that commensal GPR119 agonists regulate metabolic hormones and glucose homeostasis as efficiently as human ligands, although future studies are needed to define their potential physiological role in humans. Our results suggest that chemical mimicry of eukaryotic signalling molecules may be common among commensal bacteria and that manipulation of microbiota genes encoding metabolites that elicit host cellular responses represents a possible small-molecule therapeutic modality (microbiome-biosynthetic gene therapy).

UR - https://www.scopus.com/pages/publications/85029128985

U2 - 10.1038/nature23874

DO - 10.1038/nature23874

M3 - Article

C2 - 28854168

AN - SCOPUS:85029128985

SN - 0028-0836

VL - 549

SP - 48

EP - 53

JO - Nature

JF - Nature

IS - 7670

ER -

Commensal bacteria make GPCR ligands that mimic human signalling molecules

Abstract

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