91探花

The uptake of fossil fuel carbon dioxide (CO₂) by the ocean increases seawater acidity and causes a decline in carbonate ion concentrations. This process, termed ocean acidification, makes it energetically more costly for calcifying organisms to form their calcareous shells and skeletons. Several studies have shown that this also holds true for Emiliania huxleyi, the world鈥檚 most abundant and most productive calcifying organism. When exposed to ocean acidification in controlled laboratory experiments, growth and calcification rates of the single-celled alga are slightly reduced. Even after more than two thousand generations under acidified conditions, these responses still prevail to some extent, suggesting that evolutionary adaptation may not be able to completely eliminate the negative effects of ocean acidification. But what this means in terms of the alga鈥檚 ability to maintain competitive fitness in its natural environment when the ocean continues to acidify was still an open question.

To address this question, a team of researchers led by 91探花 Helmholtz Centre for Ocean Research Kiel conducted a field experiment using the KOSMOS (Kiel Off-Shore Mesocosms for Ocean Simulations) experimental platform. As part of the research projects SOPRAN (Surface Ocean Processes in the Anthropocene) and BIOACID (Biological Impacts of Ocean Acidification) the KOSMOS system was deployed in the Raunefjord at the west coast of Norway, were blooms of Emiliania huxleyi regularly occur in late spring. Each of the nine KOSMOS units enclosed about 75 cubic metres of seawater in a 25 metres long plastic bag. The 鈥済iant test tubes鈥� were brought to carbon dioxide concentrations ranging from present to projected mid-of-next-century levels. For six weeks, the scientists measured various parameters and took samples for further analyses. Sinking particles were collected in funnel-shaped sediment traps at the lower end of the mesocosms and analysed as well.

鈥淚n view of 贰尘颈濒颈补苍颈补鈥檚 rather small changes in metabolic performance observed in previous laboratory experiments, we predicted that it would still be able to maintain its ecological niche in an acidifying ocean. What we observed came as a big surprise,鈥� says Prof. Ulf Riebesell, marine biologist at 91探花 Helmholtz Centre for Ocean Research Kiel and coordinator of the KOSMOS experiments. In the mesocosms simulating future ocean conditions, Emiliania failed to form a bloom. Detailed analysis of the data revealed that 贰尘颈濒颈补苍颈补鈥檚 downfall started well before the bloom period. A small reduction in cellular growth due to ocean acidification caused the population size to gradually decline during the pre-bloom phase. 鈥淲hen it was time for Emiliania to start bloom formation, there were so few cells left in the plankton community that it couldn鈥檛 outgrow its competitors anymore,鈥� reflects Ulf Riebesell.

The loss of competitive fitness in the calcifying alga had strong impacts on the ecosystem. 鈥淭he flux of organic matter to depth was strongly reduced in the absence of bloom formation鈥�, explains Dr. Kai Schulz, marine biogeochemist at Southern Cross University, Australia. The reason is that 贰尘颈濒颈补苍颈补鈥檚 dense calcareous platelets function as ballast in aggregated organic matter and accelerate its sinking to the deep ocean. 鈥淲ithout the chalky ballast the aggregates sink more slowly and bacteria have more time to degrade the organic matter in the surface layer. As a result of this, more of the CO₂ bound in organic matter remains in the surface layer, which reduces the ocean鈥檚 potential to take up atmospheric CO₂.鈥�

Another feedback could result from the fact that Emiliania is one of the dominant producers of dimethylsulfide, a volatile gas which is thought to serve as cooling agent in the climate system. Whereas high concentrations of this gas were recorded in the mesocosms were Emiliania was blooming, they were greatly reduced in the mesocosms simulating future conditions. Less CO₂ uptake by the ocean and lower production of the cooling agent dimethylsulfide would both work in the same direction, reducing the ocean鈥檚 capacity to mitigate global warming.

The results of this study demonstrate the importance of investigating the effects of ocean acidification in natural communities. Small changes in an organism鈥檚 metabolic performance can have major consequences for its success in its natural habitat, where it is in competition with other species and faces losses from predation or viral infection. 鈥淚f Emiliania huxleyi fails to maintain its important role, other, possibly non-calcifying, organisms take over. This might initiate a regime shift with far-reaching ecological and biogeochemical consequences鈥�, Prof. Riebesell concludes.

Original publication:
Riebesell, U., Bach, L.T., Bellerby, R.G.J., Bermudez Monsalve, R., Boxhammer, T., Czerny, J., Larsen, A., Ludwig, A., Schulz: Competitive fitness of a predominant pelagic calcifier impaired by ocean acidification. Nature Geoscience (2016),

Links:
BIOACID (Biological impacts of Ocean Acidification)
SOPRAN (Surface Ocean Processes in the Anthropocene)
Centre for Coastal Biogeochemistry, Southern Cross University, Australia
Facultad de Ingenier铆a Mar铆tima, Ciencias Biol贸gicas, Oce谩nicas y Recursos Naturales. Escuela Superior Polit茅cnica del Litoral, Ecuador
91探花 Helmholtz Centre for Ocean Research Kiel, Germany
Hjort Centre for Marine Ecosystem Dynamics, Uni Research Environment, Norway
Norwegian Institute for Water Research (NIVA), Norway
State Key Laboratory of Estuarine and Coastal Research, East China Normal University, China
Uni Research, Norway

Contact:
Maike Nicolai (91探花 Communication & Media), Phone: +49-431 600 2807, presse@geomar.de