How microbial food web interactions shape the arctic ocean bacterial community revealed by size fractionation experiments

In the Arctic, seasonal changes are substantial, and as a result, the marine bacterial community composition and functions differ greatly between the dark winter and light‐intensive sum-mer. While light availability is, overall, the external driver of the seasonal changes, several internal biologica...

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Bibliographic Details
Published in:Microorganisms
Main Authors: Müller, Oliver, Seuthe, Lena, Pree, Bernadette, Bratbak, Gunnar, Larsen, Aud, Paulsen, Maria Lund
Format: Article in Journal/Newspaper
Language:English
Published: 2021
Subjects:
Arctic Ocean
Bacterial community structure
Experimental manipulations
Microbial food web
Microbial resilience
Phytoplankton–bacteria association
Seasonal changes
Trophic interactions
Arctic
Phytoplankton
Online Access:https://pure.au.dk/portal/da/publications/how-microbial-food-web-interactions-shape-the-arctic-ocean-bacterial-community-revealed-by-size-fractionation-experiments(bf1991bd-15ed-481c-b5f2-1ba60e476819).html
https://doi.org/10.3390/microorganisms9112378
http://www.scopus.com/inward/record.url?scp=85119058557&partnerID=8YFLogxK
Description
Summary:In the Arctic, seasonal changes are substantial, and as a result, the marine bacterial community composition and functions differ greatly between the dark winter and light‐intensive sum-mer. While light availability is, overall, the external driver of the seasonal changes, several internal biological interactions structure the bacterial community during shorter timescales. These include specific phytoplankton–bacteria associations, viral infections and other top‐down controls. Here, we uncover these microbial interactions and their effects on the bacterial community composition during a full annual cycle by manipulating the microbial food web using size fractionation. The most profound community changes were detected during the spring, with ‘mutualistic phytoplank-ton’—Gammaproteobacteria interactions dominating in the pre‐bloom phase and ‘substrate‐de-pendent phytoplankton’—Flavobacteria interactions during blooming conditions. Bacterivores had an overall limited effect on the bacterial community composition most of the year. However, in the late summer, grazing was the main factor shaping the community composition and transferring carbon to higher trophic levels. Identifying these small‐scale interactions improves our understand-ing of the Arctic marine microbial food web and its dynamics.

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