AUTHOR=Żygadłowska Olga M. , Venetz Jessica , Klomp Robin , Lenstra Wytze K. , van Helmond Niels A. G. M. , Röckmann Thomas , Wallenius Anna J. , Martins Paula Dalcin , Veraart Annelies J. , Jetten Mike S. M. , Slomp Caroline P. TITLE=Pathways of methane removal in the sediment and water column of a seasonally anoxic eutrophic marine basin JOURNAL=Frontiers in Marine Science VOLUME=10 YEAR=2023 URL=https://www.frontiersin.org/journals/marine-science/articles/10.3389/fmars.2023.1085728 DOI=10.3389/fmars.2023.1085728 ISSN=2296-7745 ABSTRACT=

Methane (CH₄) is a key greenhouse gas. Coastal areas account for a major proportion of marine CH₄ emissions. Eutrophication and associated bottom water hypoxia enhance CH₄ production in coastal sediments. Here, we assess the fate of CH₄ produced in sediments at a site in a seasonally anoxic eutrophic coastal marine basin (Scharendijke, Lake Grevelingen, the Netherlands) in spring (March) and late summer (September) in 2020. Removal of CH₄ in the sediment through anaerobic oxidation with sulfate (SO42-) is known to be incomplete in this system, as confirmed here by only slightly higher values of δ¹³C-CH₄ and δD-CH₄ in the porewater in the shallow sulfate-methane-transition zone (~5-15 cm sediment depth) when compared to deeper sediment layers. In March 2020, when the water column was fully oxygenated, CH₄ that escaped from the sediment was at least partially removed in the bottom water through aerobic oxidation. In September 2020, when the water column was anoxic below ~35 m water depth, CH₄ accumulated to high concentrations (up to 73 µmol L^-1) in the waters below the oxycline. The sharp counter gradient in oxygen and CH₄ concentrations at ~35 m depth and increase in δ¹³C-CH₄ and δD-CH₄ above the oxycline indicate mostly aerobic water column removal of CH₄. Water column profiles of particulate and dissolved Fe and Mn suggest redox cycling of both metals at the oxycline, pointing towards a potential role of metal oxides in CH₄ removal. Water column profiles of NH4+ and NO3- indicate removal of both solutes near the oxycline. Analyses of 16S rRNA gene sequences retrieved from the water column reveal the presence of aerobic CH₄ oxidizing bacteria (Methylomonadaceae) and anaerobic methanotrophic archaea (Methanoperedenaceae), with the latter potentially capable of NO3- and/or metal-oxide dependent CH₄ oxidation, near the oxycline. Overall, our results indicate sediment and water column removal of CH₄ through a combination of aerobic and anaerobic pathways, which vary seasonally. Some of the CH₄ appears to escape from the surface waters to the atmosphere, however. We conclude that eutrophication may make coastal waters a more important source of CH₄ to the atmosphere than commonly assumed.