Controls on zooplankton methane production in the central Baltic Sea

Several methanogenic pathways in oxic surface waters were recently discovered, but their relevance in the natural environment is still unknown. Our study examines distinct methane (CH4) enrichments that repeatedly occur below the thermocline during the summer months in the central Baltic Sea. In agr...

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Bibliographic Details
Published in:Biogeosciences 2019-01, Vol.16 (1), p.1-16
Main Authors: Stawiarski, Beate, Otto, Stefan, Thiel, Volker, Grawe, Ulf, Loick-Wilde, Natalie, Wittenborn, Anna K, Schloemer, Stefan, Wage, Janine, Rehder, Gregor, Labrenz, Matthias, Wasmund, Norbert, Schmale, Oliver
Format: Article
Language:English
Subjects:
Abundance
Analysis
Aquatic crustaceans
Biomarkers
Carbon 14
Cell disruption
Chemical oceanography
Copepoda
Copepods
Cyanobacteria
Defaecation
Defecation
Diet
Dinophyceae
Disruption
Dye dispersion
Environmental aspects
Faecal pellets
Food sources
Grazing
Incubation period
Lipids
Methane
Methane production
Methanogenesis
Ocean circulation
Oxidation
Physiological aspects
Phytoplankton
Plankton
Sea surface
Substrates
Sulfur oxides
Surface water
Temperature (air-sea)
Thermocline
Upwelling
Zooplankton
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Summary:Several methanogenic pathways in oxic surface waters were recently discovered, but their relevance in the natural environment is still unknown. Our study examines distinct methane (CH4) enrichments that repeatedly occur below the thermocline during the summer months in the central Baltic Sea. In agreement with previous studies in this region, we discovered differences in the methane distributions between the western and eastern Gotland Basin, pointing to in situ methane production below the thermocline in the latter (concentration of CH4 14.1±6.1 nM, δ13C CH4 −62.9 ‰). Through the use of a high-resolution hydrographic model of the Baltic Sea, we showed that methane below the thermocline can be transported by upwelling events towards the sea surface, thus contributing to the methane flux at the sea–air interface. To quantify zooplankton-associated methane production rates, we developed a sea-going methane stripping-oxidation line to determine methane release rates from copepods grazing on 14C-labelled phytoplankton. We found that (1) methane production increased with the number of copepods, (2) higher methane production rates were measured in incubations with Temora longicornis (125±49 fmol methane copepod−1 d−1) than in incubations with Acartia spp. (84±19 fmol CH4 copepod−1 d−1) dominated zooplankton communities, and (3) methane was only produced on a Rhodomonas sp. diet, and not on a cyanobacteria diet. Furthermore, copepod-specific methane production rates increased with incubation time. The latter finding suggests that methanogenic substrates for water-dwelling microbes are released by cell disruption during feeding, defecation, or diffusion from fecal pellets. In the field, particularly high methane concentrations coincided with stations showing a high abundance of DMSP/DMSO-rich Dinophyceae. Lipid biomarkers extracted from phytoplankton- and copepod-rich samples revealed that Dinophyceae are a major food source of the T. longicornis dominated zooplankton community, supporting the proposed link between copepod grazing, DMSP/DMSO release, and the build-up of subthermocline methane enrichments in the central Baltic Sea.
ISSN:1726-4189
1726-4170
1726-4189
DOI:10.5194/bg-16-1-2019