Taxonomic and functional dynamics during chytrid epidemics in an aquatic ecosystem

Fungal parasitism is common in plankton communities and plays a crucial role in the ecosystem by balancing nutrient cycling in the food web. Previous studies of aquatic ecosystems revealed that zoosporic chytrid epidemics represent an important driving factor in phytoplankton seasonal successions. I...

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Bibliographic Details
Published in:Molecular ecology Vol. 31; no. 21; pp. 5618 - 5634
Main Authors: Li, Luen‐Luen, Delgado‐Viscogliosi, Pilar, Gerphagnon, Mélanie, Viscogliosi, Eric, Christaki, Urania, Sime‐Ngando, Télesphore, Monchy, Sébastien
Format: Journal Article
Language:English
Published: England Blackwell Publishing Ltd 01-11-2022
Wiley
John Wiley and Sons Inc
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Summary:Fungal parasitism is common in plankton communities and plays a crucial role in the ecosystem by balancing nutrient cycling in the food web. Previous studies of aquatic ecosystems revealed that zoosporic chytrid epidemics represent an important driving factor in phytoplankton seasonal successions. In this study, host–parasite dynamics in Lake Pavin (France) were investigated during the spring diatom bloom while following chytrid epidemics using next generation sequencing (NGS). Metabarcoding analyses were applied to study changes in the eukaryotic microbial community throughout diatom bloom–chytrid epidemics. Relative read abundances of metabarcoding data revealed potential “beneficiaries” and “victims” during the studied period. Subsequently, metatranscriptomic analyses on samples before and during the chytrid epidemic unveiled the active part of the community and functional/metabolic dynamics in association with the progress of chytrid infection. Diatom functions involving lipases, transporters, histones, vacuolar systems, the proteasome, proteases and DNA/RNA polymerases were more abundant during the diatom bloom. Chytrid functions related to a parasitic lifestyle including invasion, colonization and stress tolerance were up‐regulated during the chytrid epidemic. In addition, functions related to the degradation/metabolism of proteins, lipids and chitin were in higher proportion in the community during the epidemic event. Results of NGS and bioinformatics analyses offered a panorama of dynamic biodiversity and biological functioning of the community.
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Handling Editor: Suhelen Egan
ISSN:0962-1083
1365-294X
DOI:10.1111/mec.16675