The Gut Microbiome of Farmed Arctic Char () is Shaped by Feeding Stage and Nutrient Presence

Overview

Journal FEMS Microbes

Publisher Oxford University Press

Specialty Microbiology

Date 2024 May 15

PMID 38745980

Authors

Stephen Knobloch

Sigurlaug Skirnisdottir

Marianne Dubois

Lucie Mayolle

Laetitia Kolypczuk

Francoise Leroi

Alexandra Leeper

Delphine Passerini

Viggo B Marteinsson

Affiliations

Soon will be listed here.

Abstract

The gut microbiome plays an important role in maintaining health and productivity of farmed fish. However, the functional role of most gut microorganisms remains unknown. Identifying the stable members of the gut microbiota and understanding their functional roles could aid in the selection of positive traits or act as a proxy for fish health in aquaculture. Here, we analyse the gut microbial community of farmed juvenile Arctic char () and reconstruct the metabolic potential of its main symbionts. The gut microbiota of Arctic char undergoes a succession in community composition during the first weeks post-hatch, with a decrease in Shannon diversity and the establishment of three dominant bacterial taxa. The genome of the most abundant bacterium, a sp., shows adaptation to rapid growth in the nutrient-rich gut environment. The second most abundant taxon, a sp., has versatile metabolic potential, including genes involved in host mucin degradation and utilization. However, during periods of absent gut content, a bacterium becomes dominant, possibly outgrowing all other bacteria through the production of secondary metabolites involved in quorum sensing and cross-inhibition while benefiting the host through short-chain fatty acid production. Whereas is often present as a symbiont in farmed salmonids, we show that the species is also detected in wild Arctic char, suggesting a close evolutionary relationship between the host and this symbiotic bacterium.

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