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8. November 2006 15:58

Life in the extreme

Cold seeps are deep-sea environments, usually a few square meters in size, where fluid is released through slow diffusion from the sea floor. Mud volcanoes which are active areas of fluid seepage, are other extreme environments discovered in the 1990s. These harsh conditions give rise to some of the most extreme and scientifically challenging environments for life to exist on the planet

Cold seeps are deep-sea environments, usually a few square meters in size, where fluid is released through slow diffusion from the sea floor. Mud volcanoes which are active areas of fluid seepage, are other extreme environments discovered in the 1990s. These harsh conditions give rise to some of the most extreme and scientifically challenging environments for life to exist on the planet.

Extensive fields of hydrocarbon-rich gas seepage, mud volcanoes and pockmarks have all been mapped by the EUROCORES programme EUROMARGINS. On 4 - 6 October 2006, scientists from 50 different research groups in 12 different countries came together in Bologna, Italy to discuss future cross-discipline, pan-European and pan-World research following in the footsteps of this four year programme as EUROMARGINS is coming to an end.

Collaboration in the ‘cold’
As ocean sediments compact in cold seeps, fluids ooze out of the sediment and into the water. The cold-seep fluids contain chemical compounds produced by the decomposition of organic materials or by inorganic chemical reactions which occur at high temperatures and pressures.

Near cold seeps in the Eastern Mediterranean, Sébastien Duperron from Université Pierre et Marie Curie in France has found unique bacterial symbiosis with mussels. Symbiotic associations between bivalves (mussels) and bacteria allow the former to benefit from the bacteria’s ability to chemosynthetically (without light) derive energy from the chemical compounds produced and use this energy to ensure primary production.

“In the bivalve species Idas sp., we have found an association with six different symbionts. This is the widest diversity of symbionts ever described in a bivalve species,” said Duperron.

This means that the mussel, depending on which type of symbionts it carries, can derive its energy from either sulphide or methane. In addition, Duperron has also found that in the Idas sp., three of the symbionts belong to bacterial groups previously not reported to include symbiotic bacteria. They seem to provide their hosts with nutrient from a yet unidentified source.

But life in these alien environments can also exist without symbionts as Ian MacDonald from Texas A&M University, Corpus Christi US has demonstrated. His observations of the fauna around coastal margin hydrocarbon seeps in the Gulf of Mexico have revealed a habitat rich in biological activity and without a need for symbionts to extract nutrients.

MacDonald found that the productivity of deep-water seeps is overwhelmingly based on chemosynthesis (deriving energy from chemical compounds instead of light) and also some chemoautotrophic symbiosis (using a symbiont to derive energy from chemical compounds).  However some communities of deep-sea corals associated with many seeps are probably filter feeders. Recent research findings indicate that the corals around the seeps may be much more widespread at seeps than previously realised. This fact adds to the biological diversity and ecological complexity of seep communities.

Underwater mud volcanoes
In the Nile deep-sea fan, mud volcanoes were discovered in the mid-1990s and they are still being investigated by a EUROMARGINS project. In the Gulf of Cadiz, the first mud volcanoes were discovered in 1999. The deepest mud volcano in this area is located at 3890m.

Luis Pinheiro from the University of Aveiro in Portugal participated in the 1999 cruise when mud volcanoes were first discovered. Pinheiro and his team have been investigating this area in close collaboration with Spain, France and Belgium. So far they have mapped 40 mud volcanoes, some as big as over 4km across and a few hundred meters high supporting characteristic ecosystems with particular faunal communities, living directly or indirectly on methane, some of which appear to represent completely new species to science.

Over four years, the EUROMARGINS have gatherered about 75 teams from 12 countries on a variety of complementary topics dedicated to the imaging, monitoring, reconstruction and modelling of the physical and chemical processes that occur in the passive margin system. Further information is available at www.esf.org/euromargins. When it comes to an end in late 2007, EUROMARGINS will be succeeded by new EUROCORES Programmes such as EuroMARC and Topo-Europe, which will both contribute to the future of European geosciences.

Media Enquiries

Dr Bernard Avril
EUROCORES Programme Coordinator for Geosciences
ESF Unit for Life, Earth and Environmental Sciences
European Science Foundation (ESF)
Tel. +33 (0)3 88 76 71 78
Fax. +33 (0)3 88 37 05 32

Sofia Valleley
EUROCORES Communications Coordinator
European Science Foundation (ESF)
Tel: +33 (0)3 88 76 21 49