MEPS 388:41-49 (2009)  -  DOI: https://doi.org/10.3354/meps08135

ABSTRACT: The CLAW hypothesis argues that a negative feedback mechanism involving phytoplankton-derived dimethylsulfoniopropionate (DMSP) could mitigate increasing sea surface temperatures that result from global warming. DMSP is converted to the climatically active dimethylsulfide (DMS), which is transferred to the atmosphere and photochemically oxidized to sulfate aerosols, leading to increases in planetary albedo and cooling of the Earth’s atmosphere. A shipboard incubation experiment was conducted to investigate the effects of increased temperature and pCO₂ on the algal community structure of the North Atlantic spring bloom and their subsequent impact on particulate and dissolved DMSP concentrations (DMSP_p and DMSP_d). Under ‘greenhouse’ conditions (elevated pCO₂; 690 ppm) and elevated temperature (ambient + 4°C), coccolithophorid and pelagophyte abundances were significantly higher than under control conditions (390 ppm CO₂ and ambient temperature). This shift in phytoplankton community structure also resulted in an increase in DMSP_p concentrations and DMSP_p:chl a ratios. There were also increases in DMSP-lyase activity and biomass-normalized DMSP-lyase activity under ‘greenhouse’ conditions. Concentrations of DMSP_d decreased in the ‘greenhouse’ treatment relative to the control. This decline is thought to be partly due to changes in the microzooplankton community structure and decreased grazing pressure under ‘greenhouse’ conditions. The increases in DMSP_p in the high temperature and greenhouse treatments support the CLAW hypothesis; the declines in DMSP_d do not.

KEY WORDS: Particulate DMSP · Dissolved DMSP · Climate change · Global warming · Carbon dioxide · Temperature · Biogeochemistry