Articles | Volume 11, issue 17
Biogeosciences, 11, 4881–4895, 2014
Biogeosciences, 11, 4881–4895, 2014

Research article 12 Sep 2014

Research article | 12 Sep 2014

Flexible C : N ratio enhances metabolism of large phytoplankton when resource supply is intermittent

D. Talmy1,2,4, J. Blackford2, N. J. Hardman-Mountford3, L. Polimene2, M. J. Follows4, and R. J. Geider1 D. Talmy et al.
  • 1School of Biological Sciences, University of Essex, Wivenhoe Park, Colchester, UK
  • 2Plymouth Marine Laboratory, Prospect Place, The Hoe, Plymouth, Devon, UK
  • 3Commonwealth Scientific and Industrial Research Organization, Marine and Atmospheric Research, Centre for Environment and Life Sciences, Floreat, Australia
  • 4Department of Earth, Atmosphere and Planetary Sciences, Massachusetts Institute of Technology, Cambridge, Massachusetts, USA

Abstract. Phytoplankton cell size influences particle sinking rate, food web interactions and biogeographical distributions. We present a model in which the uptake, storage and assimilation of nitrogen and carbon are explicitly resolved in different-sized phytoplankton cells. In the model, metabolism and cellular C : N ratio are influenced by the accumulation of carbon polymers such as carbohydrate and lipid, which is greatest when cells are nutrient starved, or exposed to high light. Allometric relations and empirical data sets are used to constrain the range of possible C : N, and indicate that larger cells can accumulate significantly more carbon storage compounds than smaller cells. When forced with extended periods of darkness combined with brief exposure to saturating irradiance, the model predicts organisms large enough to accumulate significant carbon reserves may on average synthesize protein and other functional apparatus up to five times faster than smaller organisms. The advantage of storage in terms of average daily protein synthesis rate is greatest when modeled organisms were previously nutrient starved, and carbon storage reservoirs saturated. Small organisms may therefore be at a disadvantage in terms of average daily growth rate in environments that involve prolonged periods of darkness and intermittent nutrient limitation. We suggest this mechanism is a significant constraint on phytoplankton C : N variability and cell size distribution in different oceanic regimes.

Final-revised paper