Contribution of gut microbiota to metabolism of dietary glycine betaine in mice and in vitro colonic fermentation

Valérie Micard,Natalia Rosa-Sibakov,Anna-Marja Aura,Ville M. Koistinen,Seppo Auriola,Olli Kärkkäinen,Iman Zarei,Hauke Smidt,Jenna Jokkala,Klaudyna Borewicz,Kati Hanhineva

doi:10.1186/s40168-019-0718-2

Abstract

BackgroundAccumulating evidence is supporting the protective effect of whole grains against several chronic diseases. Simultaneously, our knowledge is increasing on the impact of gut microbiota on our health and on how diet can modify the composition of our bacterial cohabitants. Herein, we studied C57BL/6 J mice fed with diets enriched with rye bran and wheat aleurone, conventional and germ-free C57BL/6NTac mice on a basal diet, and the colonic fermentation of rye bran in an in vitro model of the human gastrointestinal system. We performed 16S rRNA gene sequencing and metabolomics on the study samples to determine the effect of bran-enriched diets on the gut microbial composition and the potential contribution of microbiota to the metabolism of a novel group of betainized compounds.ResultsThe bran-enriched study diets elevated the levels of betainized compounds in the colon contents of C57BL/6 J mice. The composition of microbiota changed, and the bran-enriched diets induced an increase in the relative abundance of several bacterial taxa, including Akkermansia, Bifidobacterium, Coriobacteriaceae, Lactobacillus, Parasutterella, and Ruminococcus, many of which are associated with improved health status or the metabolism of plant-based molecules. The levels of betainized compounds in the gut tissues of germ-free mice were significantly lower compared to conventional mice. In the in vitro model of the human gut, the production of betainized compounds was observed throughout the incubation, while the levels of glycine betaine decreased. In cereal samples, only low levels or trace amounts of other betaines than glycine betaine were observed.ConclusionsOur findings provide evidence that the bacterial taxa increased in relative abundance by the bran-based diet are also involved in the metabolism of glycine betaine into other betainized compounds, adding another potential compound group acting as a mediator of the synergistic metabolic effect of diet and colonic microbiota.

Highlights

Accumulating evidence is supporting the protective effect of whole grains against several chronic diseases
We showed that one of the novel betainized compounds, 5-aminovaleric acid betaine (5AVAB), which accumulated in metabolically active tissues, such as heart and brown adipose tissue (BAT) in mice, can influence mitochondrial energy metabolism in cultured mouse cardiomyocytes by blocking β-oxidation of fatty acids to meldonium, a drug used for ischemia [35, 37]
We used two different parts of whole-grain cereals, rye bran and wheat aleurone, both of which are abundant in dietary fibre and bioactive compounds [38, 39], such as polyphenols which are known to interact with gut microbiota

Summary

Introduction

Accumulating evidence is supporting the protective effect of whole grains against several chronic diseases. We performed 16S rRNA gene sequencing and metabolomics on the study samples to determine the effect of bran-enriched diets on the gut microbial composition and the potential contribution of microbiota to the metabolism of a novel group of betainized compounds. Despite the strong evidence for the beneficial health effects of whole grains, the underlying molecular mechanisms responsible for these effects have remained elusive. Most likely, they are related to the presence of the nutrient-dense bran compartment, rich in fibre, micronutrients, and phytochemicals, retained in whole-grain foods [26,27,28]

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