Résumé
Phytoplankton growth in the seasonally productive Southern Ocean is typically limited by iron (Fe). In the next century, however, Fe inputs and temperature are predicted to increase. Dissolved concentrations of nitrogen (N) and phosphorus (P) may also change due to physical and biological drivers, altering the stoichiometric N:P ratio of the water column. Two separate experiments were conducted to study how these predicted changes will impact nutrient utilization by two natural microbial communities from the Ross Sea, Antarctica. The first investigation focused on a Terra Nova Bay community amended with Fe and grown under a wide range of seven different N:P ratios. Building on the results of the first study, a McMurdo Sound community was incubated under a factorial design at high, medium (ambient), and low N:P ratios, with and without Fe addition, and at ambient versus elevated temperature. In both experiments absolute uptake rates of bicarbonate, nitrate, and amino acids by two size fractions (0.7–5.0 μm and > 5.0 μm) of microorganisms were measured using stable isotopes. For Terra Nova Bay microorganisms, significant differences in nutrient uptake rates occurred when the N:P ratio was elevated, and nitrate uptake rates significantly increased early in the experiment but were not different at the end. For McMurdo Sound microorganisms, changing the N:P supply ratio did not have a clear effect, while temperature elevation and/or Fe addition significantly increased nutrient uptake. Results indicate that changing the dissolved N:P ratio can potentially alter nutrient uptake rates; however, the impact of temperature and Fe are greater.
| Langue d'origine | English |
|---|---|
| Pages (de-à) | 2955-2975 |
| Nombre de pages | 21 |
| Journal | Journal of Geophysical Research G: Biogeosciences |
| Volume | 123 |
| Numéro de publication | 9 |
| DOI | |
| Statut de publication | Published - sept. 2018 |
Note bibliographique
Funding Information:Thanks to Quinn Roberts, Marta Sanderson, and Steven Baer for their help in the field and with laboratory analyses. We are grateful for Nancy Tenenbaum for meticulously identifying and counting phytoplankton cells. We acknowledge Jen Erxleben and Ned Corkran and the other Antarctic Support Contractors who made this research possible. Feedback from reviewers, Elizabeth Canuel, Michael Lomas, Deborah Steinberg, and Peter Van Veld improved the manuscript. This work was supported by grant 1043635, 1043671, and 1043748, awarded to D. A. Bronk, A. E. Allen, and D. A. Hutchins, respectively, from the National Science Foundation; J. L. Spackeen also received support from NSF GK-12 (DGE-0840804). The authors cite no conflict of interests. Data supporting this work are found within the manuscript or as tables and figures in the supporting information. Any additional data can be obtained from the corresponding author. This paper is Contribution 3373 of the Virginia Institute of Marine Science.
Publisher Copyright:
©2018. American Geophysical Union. All Rights Reserved.
ASJC Scopus Subject Areas
- Soil Science
- Forestry
- Water Science and Technology
- Palaeontology
- Atmospheric Science
- Aquatic Science
- Ecology