Bifidobacterium adolescentis as a key member of the human gut microbiota in the production of GABA.

Gamma aminobutyric acid (GABA) is the principal inhibitory neurotransmitter playing a key role in anxiety and depression disorders in mammals. Recent studies revealed that members of the gut microbiota are able to produce GABA modulating the gut-brain axis response. Among members of the human gut microbiota, bifidobacteria are well known to establish many metabolic and physiologic interactions with the host. In this study, we performed genome analyses of more than 1,000 bifidobacterial strains publicly available revealing that Bifidobacterium adolescentis taxon might represent a model GABA producer in human gastrointestinal tract. Moreover, the in silico screening of human/animal metagenomic datasets showed an intriguing association/correlation between B. adolescentis load and mental disorders such as depression and anxiety. Interestingly, in vitro screening of 82 B. adolescentis strains allowed identifying two high GABA producers, i.e. B. adolescentis PRL2019 and B. adolescentis HD17T2H, which were employed in an in vivo trial in rats. Feeding Groningen rats with a supplementation of B. adolescentis strains, confirmed the ability of these microorganisms to stimulate the in vivo production of GABA highlighting their potential implication in gut-brain axis interactions.

Compositional assessment of bacterial communities in probiotic supplements by means of metagenomic techniques.

Health promoting or probiotic bacteria are commonly incorporated into a variety of functional foods and drug formulations, due to their purported ability to confer benefit to host health. Despite the extensive commercial exploitation of probiotic formulations there are still major knowledge gaps regarding the precise molecular mechanism of action and corresponding genetic/genomic properties of probiotic bacteria. In the current study, we describe a metagenomic approach which allows determination of the composition of probiotic supplements through next-generation sequencing analyses based on rRNA-associated sequences to assess bacterial composition of the product combined with a shotgun metagenomics approach directed to decode the genome sequences of the probiotic strains for each product assayed. The here developed approach has been tested for 10 probiotic supplements, revealing inconsistencies between the identified probiotic strains and the declared strains as indicated by the producers. Furthermore, the decoded bacterial genome sequence of Bifidobacterium animalis subsp. lactis BB-12 from a 1995 frozen dried stock revealed genetic evidence for genome evolution and stability of this microorganism when compared with the re-constructed genome of the identical strain from a probiotic supplement of 2017.