Evaluating Microbiome-directed Fibre Snacks in Gnotobiotic Mice and Humans

Overview

Journal Nature

Specialty Science

Date 2021 Jun 24

PMID 34163075

Citations 51

Authors

Omar Delannoy-Bruno

Chandani Desai

Arjun S Raman

Robert Y Chen

Matthew C Hibberd

Jiye Cheng

Nathan Han

Juan J Castillo

Garret Couture

Carlito B Lebrilla

Ruteja A Barve

Vincent Lombard

Bernard Henrissat

Semen A Leyn

Dmitry A Rodionov

Andrei L Osterman

David K Hayashi

Alexandra Meynier

Sophie Vinoy

Kyleigh Kirbach

Tara Wilmot

Andrew C Heath

Samuel Klein

Michael J Barratt

Jeffrey I Gordon

Affiliations

Soon will be listed here.

Abstract

Changing food preferences brought about by westernization that have deleterious health effects-combined with myriad forces that are contributing to increased food insecurity-are catalysing efforts to identify more nutritious and affordable foods. Consumption of dietary fibre can help to prevent cardiovascular disease, type 2 diabetes and obesity. A substantial number of reports have explored the effects of dietary fibre on the gut microbial community. However, the microbiome is complex, dynamic and exhibits considerable intra- and interpersonal variation in its composition and functions. The large number of potential interactions between the components of the microbiome makes it challenging to define the mechanisms by which food ingredients affect community properties. Here we address the question of how foods containing different fibre preparations can be designed to alter functions associated with specific components of the microbiome. Because a marked increase in snack consumption is associated with westernization, we formulated snack prototypes using plant fibres from different sustainable sources that targeted distinct features of the gut microbiomes of individuals with obesity when transplanted into gnotobiotic mice. We used these snacks to supplement controlled diets that were consumed by adult individuals with obesity or who were overweight. Fibre-specific changes in their microbiomes were linked to changes in their plasma proteomes indicative of an altered physiological state.

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