Abstract

Diazotrophic inputs by Trichodesmium have been shown to support production in tropical and subtropical marine environments, but the importance of Trichodesmium in the Gulf of Mexico has not been widely investigated. Here, we use stable carbon ( 13 C) and nitrogen ( 15 N) isotopes to determine whether diazotrophy impacts the isotope baselines of pelagic food webs in the northern Gulf of Mexico. Phytoplankton (measured as particulate organic matter), Trichodesmium, and zooplankton were collected from neritic and oceanic environments (salinity < 32 and 32, respectively). Our results show that zooplankton in both regions exhibited 13 C values that were constrained between -20 and -18 , which reflects the use of carbon from both Trichodesmium and other phytoplankton. Despite the utilization of similar carbon sources, zooplankton 15 N values were significantly higher in neritic (mean SD = 5.4 1.1 ) compared to oceanic samples (2.8 1.4 ). We attribute the difference in nitrogen isotope values to the use of isotopically light nitrogen derived from diazotrophy in oceanic environments compared to enriched nitrogen from terrestrial sources transported by rivers in neritic areas. A comparison with published food web data from the Gulf of Mexico shows that disparate 15 N values which parallel our data suggest differential nitrogen cycling throughout the basin. The results of the present study indicate that diazotrophy impacts the estimation of consumer trophic positions by altering the 15 N values of organisms at the base of the food web. N 2 fixation and freshwater inputs should be considered in future efforts to describe pelagic food webs in the Gulf of Mexico.