Finding Functional Differences Between Species in a Microbial Community: Case Studies in Wine Fermentation and Kefir Culture

Overview

Journal Front Microbiol

Specialty Microbiology

Date 2019 Jul 12

PMID 31293529

Citations 8

Authors

Chrats Melkonian

Willi Gottstein

Sonja Blasche

Yongkyu Kim

Martin Abel-Kistrup

Hentie Swiegers

Sofie Saerens

Nathalia Edwards

Kiran R Patil

Bas Teusink

Douwe Molenaar

Affiliations

Soon will be listed here.

Abstract

Microbial life usually takes place in a community where individuals interact, by competition for nutrients, cross-feeding, inhibition by end-products, but also by their spatial distribution. Lactic acid bacteria are prominent members of microbial communities responsible for food fermentations. Their niche in a community depends on their own properties as well as those of the other species. Here, we apply a computational approach, which uses only genomic and metagenomic information and functional annotation of genes, to find properties that distinguish a species from others in the community, as well as to follow individual species in a community. We analyzed isolated and sequenced strains from a kefir community, and metagenomes from wine fermentations. We demonstrate how the distinguishing properties of an organism lead to experimentally testable hypotheses concerning the niche and the interactions with other species. We observe, for example, that , a dominant organism in kefir, stands out among the because it potentially has more amino acid auxotrophies. Using metagenomic analysis of industrial wine fermentations we investigate the role of an inoculated in malolactic fermentation. We observed that thrives better on white than on red wine fermentations and has the largest number of phosphotransferase system among the bacteria observed in the wine communities. Also, together with , and genera had the highest number of genes involved in biosynthesis of amino acids.

Citing Articles

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Microbial interactions shape cheese flavour formation.

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