Coral itself may play important role in regulating local climate: Coral chemicals protect against warming oceans
- Date:
- October 23, 2013
- Source:
- Science in Public
- Summary:
- Australian marine scientists have found the first evidence that coral itself may play an important role in regulating local climate. They have discovered that the coral animal -- not just its algal symbiont -- makes an important sulfur-based molecule with properties to assist it in many ways, ranging from cellular protection in times of heat stress to local climate cooling by encouraging clouds to form.
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A new article reveals coral animals produce the 'smell of the ocean' -- influencing cloud formation and protecting themselves against rising seawater temperatures.
Australian marine scientists have found the first evidence that coral itself may play an important role in regulating local climate.
They have discovered that the coral animal -- not just its algal symbiont -- makes an important sulphur-based molecule with properties to assist it in many ways, ranging from cellular protection in times of heat stress to local climate cooling by encouraging clouds to form.
These findings have been published in the science journal Nature.
The researchers have shown that the coral animal makes dimethylsulphoniopropionate (DMSP). "The characteristic 'smell of the ocean' is actually derived from this compound, indicating how abundant the molecule is in the marine environment. In fact we could smell it in a single baby coral," says AIMS chemist Cherie Motti, and co-author on the paper.
"This is the first time that an animal has been identified as a DMSP producer. Previously it was assumed that the large concentrations of DMSP emitted from coral reefs came solely from their symbiotic algae," says lead author Jean-Baptiste Raina, of AIMS@JCU and the ARC Centre of Excellence for Coral Reef Studies at James Cook University (CoECRS).
Production of DMSP was found to increase when corals are subjected to water temperatures that put them under heat stress. DMSP and its breakdown products act as antioxidants (chemical defence compounds) protecting coral tissues from environmental stress, including that caused by high solar radiation.
The sulphur-based molecules also serve as nuclei for the formation of water droplets in the atmosphere -- and hence help to create clouds. If coral numbers decline, the scientists warn, there could be a major decrease in the production of DMSP and this, in turn, will impede cloud formation.
"Cloud production, especially in the tropics, is an important regulator of climate -- because clouds shade Earth and reflect much of the sun's heat back into space. If fewer clouds are produced, less heat will be reflected -- which ultimately will lead to warmer sea surface temperatures," Dr Raina explains.
Australia's Great Barrier Reef is a major hotspot for the emission of sulphur aerosol particles, according to the scientists. "The GBR is the largest biological structure on the planet and the release of these particles along its 2600 km length could constitute a major source of cloud condensation nuclei," the authors write in their paper.
"Considering declining trends in coral cover and predicted increases in coral mortality worldwide caused by anthropogenic stressors, the associated decline in sulphur aerosol production from coral reefs may further destabilise local climate regulation and accelerate degradation of this globally important and diverse ecosystem."
The researchers are from the Australian Institute of Marine Science (AIMS), the ARC Centre of Excellence for Coral Reef Studies at James Cook University (CoECRS), the University of Western Australia (UWA), Murdoch University (MU) and the Australian National University (ANU).
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Journal Reference:
- Jean-Baptiste Raina, Dianne M. Tapiolas, Sylvain Forêt, Adrian Lutz, David Abrego, Janja Ceh, François O. Seneca, Peta L. Clode, David G. Bourne, Bette L. Willis, Cherie A. Motti. DMSP biosynthesis by an animal and its role in coral thermal stress response. Nature, 2013; DOI: 10.1038/nature12677
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