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The impact of surface-adsorbed phosphorus on phytoplankton Redfield stoichiometry

Sergio A. Sañudo-Wilhelmy (), Antonio Tovar-Sanchez, Fei-Xue Fu, Douglas G. Capone, Edward J. Carpenter and David A. Hutchins
Additional contact information
Sergio A. Sañudo-Wilhelmy: Stony Brook University
Antonio Tovar-Sanchez: Stony Brook University
Fei-Xue Fu: University of Delaware
Douglas G. Capone: University of Southern California
Edward J. Carpenter: San Francisco State University
David A. Hutchins: University of Delaware

Nature, 2004, vol. 432, issue 7019, 897-901

Abstract: Abstract The Redfield ratio of 106 carbon:16 nitrogen:1 phosphorus in marine phytoplankton1 is one of the foundations of ocean biogeochemistry, with applications in algal physiology2, palaeoclimatology3 and global climate change4. However, this ratio varies substantially in response to changes in algal nutrient status5 and taxonomic affiliation6,7. Here we report that Redfield ratios are also strongly affected by partitioning into surface-adsorbed and intracellular phosphorus pools. The C:N:surface-adsorbed P (80–105 C:15–18 N:1 P) and total (71–80 C:13–14 N:1 P) ratios in natural populations and cultures of Trichodesmium were close to Redfield values and not significantly different from each other. In contrast, intracellular ratios consistently exceeded the Redfield ratio (316–434 C:59–83 N:1 intracellular P). These high intracellular ratios were associated with reduced N2 fixation rates, suggestive of phosphorus deficiency. Other algal species also have substantial surface-adsorbed phosphorus pools, suggesting that our Trichodesmium results are generally applicable to all phytoplankton. Measurements of the distinct phytoplankton phosphorus pools may be required to assess nutrient limitation accurately from elemental composition. Deviations from Redfield stoichiometry may be attributable to surface adsorption of phosphorus rather than to biological processes, and this scavenging could affect the interpretation of marine nutrient inventories and ecosystem models.

Date: 2004
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DOI: 10.1038/nature03125

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