Bibliographic Details
| Title: |
The core microbiomes and associated metabolic potential of water kefir as revealed by pan multi-omics. |
| Authors: |
Breselge, Samuel, Skibinska, Iwona, Yin, Xiaofei, Brennan, Lorraine, Kilcawley, Kieran, Cotter, Paul D. |
| Source: |
Communications Biology; 3/11/2025, Vol. 8 Issue 1, p1-16, 16p |
| Subject Terms: |
LIFE sciences, MICROBIAL diversity, MULTIOMICS, KEFIR, METABOLOMICS, FERMENTED beverages |
| Abstract: |
Water kefir (WK) is an artisanal fermented beverage made from sugary water, optional fruits and WK grains. WK grains can be reused to start new fermentations. Here we investigate the microbial composition and function of 69 WK grains and their ferments by shotgun metagenomics. A subset of samples was subjected to metabolomic, including volatilomic, analysis. The impact of different fermentation practices on microbial composition and fermentation characteristics was analysed and it was noted that, for example, the common practice of drying water kefir grains significantly reduces microbial diversity and negatively impacts subsequent grain growth. Metagenomic analysis allowed the detection of 96 species within WK, the definition of core genera and the detection of different community states after 48 h of fermentation. A total of 485 bacterial metagenome assembled genomes were obtained and 18 putatively novel species were predicted. Metabolite and volatile analysis show associations between key species with flavour compounds. We show the complex microbial composition of WK and links between fermentation practices, microbes and the fermented product. The results can be used as a foundation for the selection of species for large scale WK production with desired flavour profiles and to guide the regulatory framework for commercial WK production. Pan multi-omic analysis sheds light on the core microbiomes, community states, metabolic potential, and other characteristics of the fermented beverage water kefir. [ABSTRACT FROM AUTHOR] |
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| Database: |
Complementary Index |
