Nitrogen-fixing sulfate reducing bacteria in shallow coastal sediments under simulated resuspension

Nitrogen (N2) fixation by heterotrophic non-cyanobacterial diazotrophs is common in marine deep-sea sedi-ments. However, in shallow coastal areas, where resuspension of sediments is extensive, the magnitude of sediment-associated N2 fixation during resuspension is unknown. We examined nitrogen fixation in dark slurry incubations with sediments (0-5 cm and 0-10 cm depths) under simulated resuspension from five shallow stations (water depth <1 m) and an anoxic site in the Bay of Gdansk (109 m) in the Baltic Sea. Abiotic variables and the composition of nitrogen fixing organisms (diazotrophs) were measured at the study sites. To estimate the contribution of nitrogen fixing sulfate reducing bacteria to total nitrogen fixation, parallel incubations with sodium molybdate as inhibitor were performed. Our data show low but variable nitrogen fixation rates (n.d. -23.7 nmol N g-1 d-1), promoted in small-grained sediments associated with increased organic carbon content and high nutrient concentrations in pore waters. Highest nitrogen fixation at the shallow sites was encountered in the upper 0-5 cm of the sediments while rates were negligible below. Sulfate reducing bacteria (e.g. Desulfo-bacterales and Desulfovibrionales) were responsible for most of the heterotrophic nitrogen fixation and appear as key players for pelagic N2 fixation during resuspension. Our study reveals an important sediment - water coupling, which may be accentuated by the increased storms and resuspension events predicted for the Baltic Sea region.

Automated summary

Nitrogen fixation by heterotrophic non-cyanobacterial diazotrophs is observed in marine deep-sea sediments. In this study, the researchers found that sediment-associated nitrogen fixation during resuspension is influenced by small-grained sediments, organic carbon content, and nutrient concentrations in pore waters. Sulfate reducing bacteria, such as Desulfo-bacterales and Desulfovibrionales, play a significant role in heterotrophic nitrogen fixation during resuspension.