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Nature 455, 387-390 (18 September 2008) | doi:10.1038/nature07235; Received 17 March 2008; Accepted 4 July 2008; Published online 20 August 2008

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Counterintuitive carbon-to-nutrient coupling in an Arctic pelagic ecosystem

T. F. Thingstad1, R. G. J. Bellerby2,3, G. Bratbak1, K. Y. Børsheim4, J. K. Egge1, M. Heldal1, A. Larsen1, C. Neill2, J. Nejstgaard1, S. Norland1, R.-A. Sandaa1, E. F. Skjoldal1, T. Tanaka5, R. Thyrhaug1 & B. Töpper1

  1. Department of Biology, University of Bergen, Jahnebakken 5PO Box 7800, 5020 Bergen, Norway
  2. Bjerknes Centre for Climate Research, Allégaten 55, 5007 Bergen, Norway
  3. Geophysical Institute, University of Bergen, Allégaten 70, 5007 Bergen, Norway
  4. Institute of Marine Research, PO Box 1870, Nordnes 5817 Bergen, Norway
  5. Laboratoire d'Océanographie et de Biogéochimie, UMR6535-CNRS, Campus de Luminy, Case 901, 13288 Marseille CEDEX09, France

Correspondence to: T. F. Thingstad1 Correspondence and requests for materials should be addressed to T.F.T. (Email: frede.thingstad@bio.uib.no).

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Predicting the ocean's role in the global carbon cycle requires an understanding of the stoichiometric coupling between carbon and growth-limiting elements in biogeochemical processes. A recent addition to such knowledge is that the carbon/nitrogen ratio of inorganic consumption and release of dissolved organic matter may increase in a high-CO2 world1. This will, however, yield a negative feedback on atmospheric CO2 only if the extra organic material escapes mineralization within the photic zone. Here we show, in the context of an Arctic pelagic ecosystem, how the fate and effects of added degradable organic carbon depend critically on the state of the microbial food web. When bacterial growth rate was limited by mineral nutrients, extra organic carbon accumulated in the system. When bacteria were limited by organic carbon, however, addition of labile dissolved organic carbon reduced phytoplankton biomass and activity and also the rate at which total organic carbon accumulated, explained as the result of stimulated bacterial competition for mineral nutrients. This counterintuitive 'more organic carbon gives less organic carbon' effect was particularly pronounced in diatom-dominated systems where the carbon/mineral nutrient ratio in phytoplankton production was high. Our results highlight how descriptions of present and future states of the oceanic carbon cycle require detailed understanding of the stoichiometric coupling between carbon and growth-limiting mineral nutrients in both autotrophic and heterotrophic processes.