Denitrification Dominates Sediment Nitrogen Removal and Is Enhanced by Bottom-Water Hypoxia in the Northern Gulf of Mexico

Abstract

Nutrient loads from the Mississippi River watershed are associated with seasonal development of bottom-water hypoxia in the northern Gulf of Mexico. Microbial nitrogen (N) transformations at the sediment-water interface are important in determining system productivity and the development and maintenance of hypoxia. Intact sediment cores were incubated in a continuous-flow system with stable isotope tracers to identify and quantify important N sources (e.g., N fixation), sinks (e.g., denitrification and anammox), and links (e.g., dissimilatory nitrate reduction to ammonium, DNRA). Microbial N sinks on the Louisiana-Texas continental shelf remove up to 68 % of the total N load from the Mississippi River watershed, and up to 29 % of this N removal (mean = 11.8 ± 1.7 %) may be due to anammox. The highest N2 production rates and ammonium effluxes were observed at low bottom-water oxygen concentrations, and sediments were a significant source of ammonium to the water column at all times. DNRA and heterotrophic N fixation were not consistent pathways for total sediment N fluxes, but their potential importance to N balance and productivity in the system warrants further study and inclusion in ecosystem models. Physical disturbance from passage of two hurricanes in 2008 resulted in lower N cycling rates and sediment oxygen consumption, with sediment processes migrating into the water column. Denitrification is the dominant N sink in the northern Gulf of Mexico and provides a valuable ecosystem service by mitigating N loads from the Mississippi River watershed, particularly during seasonal bottom-water hypoxia events.