Abstract: Dimensions of biodiversity of oceanic nitrogen cycling: nutrient co-limitation, nitrogen substrate preferences and more. (2016 Ocean Sciences Meeting)

Dimensions of biodiversity of oceanic nitrogen cycling: nutrient co-limitation, nitrogen substrate preferences and more.

Jonathan Zehr¹, Matthew M Mills², Irina N Shilova³, Kendra Turk-Kubo³, Julie Robidart⁴, Gert van Dijken², Karin M Bjorkman⁵, Daniel B Whitt⁶, Brenner Wai⁵, Joaquin Pampin Baro⁷, Mary Hogan³, Insa Rapp⁸, Emily Zakem⁹, A Fredrickson³, Brian Leahy², Morgan Linney⁵, Alessandra Santiago², Michael J Follows¹⁰, Eric P. Achterberg⁸, Zbigniew Kolber¹¹, Matthew J Church¹² and Kevin R Arrigo², (1)University of California, Santa Cruz, Ocean Sciences Department, Santa Cruz, CA, United States, (2)Stanford University, Earth System Science, Stanford, CA, United States, (3)University of California Santa Cruz, Ocean Sciences, Santa Cruz, CA, United States, (4)National Oceanographic Centre, Southampton, United Kingdom, (5)University of Hawai'i, SOEST, Honolulu, HI, United States, (6)University of Cambridge, Cambridge, United Kingdom, (7)GEOMAR, Germany, (8)Geomar - Hemholtz Centre for Ocean Research, Chemical Oceanography, Kiel, Germany, (9)MIT, Earth Atmosphere and Planetary Science, Cambridge, MA, United States, (10)Massachusetts Inst Tech, Cambridge, MA, United States, (11)University of California, Institute of Marine Sciences, Santa Cruz, CA, United States, (12)University of Hawaii at Manoa, Honolulu, HI, United States

Abstract:

We conducted the research cruise: Nutrient Effects on Marine microOrganisms (NEMO) onboard the R/V New Horizon (NH1417: August 18 to September 16, 2014) between the ports of San Diego, CA and Honolulu, HI. The three major objectives of the cruise were to: 1) evaluate genetic, physiological and phylogenetic responses of marine phytoplankton communities in the North Pacific Subtropical Gyre to different nitrogen (N) substrates and to determine how other nutrients (iron, phosphorus) impact N utilization; 2) characterize the physical processes and dynamics in support of the biological processes; and 3) characterize the diversity and activities of microbial communities in the upper water column in relation to the nutrient availability. Several incubation experiments were conducted along the cruise transect to assess the effect of nutrients on microbial communities. The results showed that N addition resulted in increased chlorophyll a (chl a) and rates of CO₂ fixation at most sites, but Prochlorococcus, Synechococcus and picoekaryotic phytoplankton had different responses to urea, ammonium and nitrate. In contrast, chl a and CO₂ fixation did not respond to additions of single nutrient (e.g. N, P or Fe alone) at the westernmost experiment (151°W), where the simultaneous addition of N and P was required for stimulation. The physical dynamics were studied through high-resolution surveys of eddy dipole features as well as diel sampling at two locations. Additionally, we characterized an extensive bloom that occurred near the critical latitude (29°N, 140°W) from mid July to the end of September; a typical but still enigmatic event. Here, we present a summary of the initial observations and findings from the NEMO cruise with data including physics, nutrient concentrations, chl a, primary productivity and microbial community composition. The results of this research cruise will help in assessing how ocean N cycling and ecosystem functions will respond to global climate change.

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