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In vitro modeling of bile acid processing by the human fecal microbiota

In vitro modeling of bile acid processing by the human fecal microbiota
In vitro modeling of bile acid processing by the human fecal microbiota

Bile acids, the products of concerted host and gut bacterial metabolism, have important signaling functions within the mammalian metabolic system and a key role in digestion. Given the complexity of the mega-variate bacterial community residing in the gastrointestinal tract, studying associations between individual bacterial genera and bile acid processing remains a challenge. Here, we present a novel in vitro approach to determine the bacterial genera associated with the metabolism of different primary bile acids and their potential to contribute to inter-individual variation in this processing. Anaerobic, pH-controlled batch cultures were inoculated with human fecal microbiota and treated with individual conjugated primary bile acids (500 μg/ml) to serve as the sole substrate for 24 h. Samples were collected throughout the experiment (0, 5, 10, and 24 h) and the bacterial composition was determined by 16S rRNA gene sequencing and the bile acid signatures were characterized using a targeted ultra-performance liquid chromatography-mass spectrometry (UPLC-MS) approach. Data fusion techniques were used to identify statistical bacterial-metabolic linkages. An increase in gut bacteria associated bile acids was observed over 24 h with variation in the rate of bile acid metabolism across the volunteers (n = 7). Correlation analysis identified a significant association between the Gemmiger genus and the deconjugation of glycine conjugated bile acids while the deconjugation of taurocholic acid was associated with bacteria from the Eubacterium and Ruminococcus genera. A positive correlation between Dorea and deoxycholic acid production suggest a potential role for this genus in cholic acid dehydroxylation. A slower deconjugation of taurocholic acid was observed in individuals with a greater abundance of Parasutterella and Akkermansia. This work demonstrates the utility of integrating compositional (metataxonomics) and functional (metabonomics) systems biology approaches, coupled to in vitro model systems, to study the biochemical capabilities of bacteria within complex ecosystems. Characterizing the dynamic interactions between the gut microbiota and the bile acid pool enables a greater understanding of how variation in the gut microbiota influences host bile acid signatures, their associated functions and their implications for health.

1664-302X
1-13
Martin, Glynn
011e1907-49a8-45d5-a57d-ef21f521872f
Kolida, Sofia
7fa76a41-9db6-4c79-a0f9-969be2aa31ca
Marchesi, Julian R.
8945c0ab-7c63-44dd-a39c-3d084152959f
Want, Elizabeth
eb9c86c9-75ae-4690-9571-25039ba2c559
Sidaway, James E.
923e9eeb-28a2-4fea-953e-fe43b7c4d652
Swann, Jonathan R.
7c11a66b-f4b8-4dbf-aa17-ad8b0561b85c
Martin, Glynn
011e1907-49a8-45d5-a57d-ef21f521872f
Kolida, Sofia
7fa76a41-9db6-4c79-a0f9-969be2aa31ca
Marchesi, Julian R.
8945c0ab-7c63-44dd-a39c-3d084152959f
Want, Elizabeth
eb9c86c9-75ae-4690-9571-25039ba2c559
Sidaway, James E.
923e9eeb-28a2-4fea-953e-fe43b7c4d652
Swann, Jonathan R.
7c11a66b-f4b8-4dbf-aa17-ad8b0561b85c

Martin, Glynn, Kolida, Sofia, Marchesi, Julian R., Want, Elizabeth, Sidaway, James E. and Swann, Jonathan R. (2018) In vitro modeling of bile acid processing by the human fecal microbiota. Frontiers in Microbiology, 9, 1-13, [1153]. (doi:10.3389/fmicb.2018.01153).

Record type: Article

Abstract

Bile acids, the products of concerted host and gut bacterial metabolism, have important signaling functions within the mammalian metabolic system and a key role in digestion. Given the complexity of the mega-variate bacterial community residing in the gastrointestinal tract, studying associations between individual bacterial genera and bile acid processing remains a challenge. Here, we present a novel in vitro approach to determine the bacterial genera associated with the metabolism of different primary bile acids and their potential to contribute to inter-individual variation in this processing. Anaerobic, pH-controlled batch cultures were inoculated with human fecal microbiota and treated with individual conjugated primary bile acids (500 μg/ml) to serve as the sole substrate for 24 h. Samples were collected throughout the experiment (0, 5, 10, and 24 h) and the bacterial composition was determined by 16S rRNA gene sequencing and the bile acid signatures were characterized using a targeted ultra-performance liquid chromatography-mass spectrometry (UPLC-MS) approach. Data fusion techniques were used to identify statistical bacterial-metabolic linkages. An increase in gut bacteria associated bile acids was observed over 24 h with variation in the rate of bile acid metabolism across the volunteers (n = 7). Correlation analysis identified a significant association between the Gemmiger genus and the deconjugation of glycine conjugated bile acids while the deconjugation of taurocholic acid was associated with bacteria from the Eubacterium and Ruminococcus genera. A positive correlation between Dorea and deoxycholic acid production suggest a potential role for this genus in cholic acid dehydroxylation. A slower deconjugation of taurocholic acid was observed in individuals with a greater abundance of Parasutterella and Akkermansia. This work demonstrates the utility of integrating compositional (metataxonomics) and functional (metabonomics) systems biology approaches, coupled to in vitro model systems, to study the biochemical capabilities of bacteria within complex ecosystems. Characterizing the dynamic interactions between the gut microbiota and the bile acid pool enables a greater understanding of how variation in the gut microbiota influences host bile acid signatures, their associated functions and their implications for health.

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Accepted/In Press date: 14 May 2018
e-pub ahead of print date: 5 June 2018
Published date: 2018

Identifiers

Local EPrints ID: 440848
URI: http://eprints.soton.ac.uk/id/eprint/440848
ISSN: 1664-302X
PURE UUID: 2cbae6b9-162f-4c58-b35e-4cde2dceeda4
ORCID for Jonathan R. Swann: ORCID iD orcid.org/0000-0002-6485-4529

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Date deposited: 20 May 2020 16:31
Last modified: 17 Mar 2024 04:00

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Contributors

Author: Glynn Martin
Author: Sofia Kolida
Author: Julian R. Marchesi
Author: Elizabeth Want
Author: James E. Sidaway

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