Press release from Mai 13th, 2008

Deep Sea Methane Scavengers Captured

Leipzig / Pasadena. Scientists of the Helmholtz Centre for Environmental Research (UFZ) in Leipzig and the California Institute of Technology (Caltech) in Pasadena succeeded in capturing syntrophic (means “feeding together”) microorganisms that are known to dramatically reduce the oceanic emission of methane into the atmosphere. These microorganisms that oxidize methane anaerobically are an important component of the global carbon cycle and a major sink for methane on Earth. Methane – a more than 20 times stronger greenhouse gas than carbon dioxide – constantly seeps out large methane hydrate reservoirs in the ocean floors, but 80 percent of it are immediately consumed by these microorganisms. The importance of the anaerobic oxidation of methane for the Earth’s climate is known since 1999 and various international research groups work on isolating the responsible microorganisms, so far with little success.

Anaerobes Methanoxidierer-Konsortium

Anaerobic methane oxidizing consortium: Archaea in red, Sulfate Reducing Bacteria in green. Microscopic image shows a consortium after fluorescent in situ hybridization (CARD-FISH). The samples are taken from deep sea sediments off the coast of California, Monterey Bay.
Source: Annelie Pernthaler/UFZ

download as jpg (0.5 MB)

Anaerobes Methanoxidierer-Konsortium

Anaerobic methane oxidizing consortium
Source: Annelie Pernthaler/UFZ

download as jpg (0.5 MB)

Pernthaler and co-workers developed a new molecular technique to selectively separate these microorganisms from their natural complex community, and subsequently sequenced their genome. The findings were exciting: Besides identifying all genes responsible for the anaerobic oxidation of methane, new bacterial partners of this syntrophic association were discovered and the ability to fix N2 could be demonstrated. The work has been published in the current issue of the renowned Journal Proceedings of the National Academy of Sciences (PNAS).

The beauty of small things revealed

Microorganisms are the unseen majority on our planet: There are more than 100 Million times more microbial cells than stars in the visible universe, accounting for more than 90 percent of the Earth’s biomass. Yet, we have little idea what most of these bacteria and archaea are doing. It is not only their small size that makes them hard to study. Most microorganisms can not be grown, and thus studied, in the lab. But recent developments of new molecular techniques allow the study of microorganisms where they live: In nature. This is leading to an explosion of knowledge with no end in sight. One of these techniques is genome sequencing – learning about the genetic make-up of an organism. This works well for single organisms, such as the sequencing of the human genome. The complexity of natural microbial communities, however, is a major problem. The vast collection of genes can often not be linked to an organism or a physiological process. This plenitude of general information can be compared to a one-billion pieces puzzle of which you own only 300 pieces and you have to try to find out where which piece belongs and how the whole picture could look like.

Scientist at UFZ and Caltech now developed a method that solves this problem. Pernthaler and co-workers attached small ironbeads to the microorganisms of interest and pulled them out of the deep sea sediment by simply applying a magnet. These microbes are Archaea, which cooperate with sulfate reducing Bacteria to perform a thermodynamically tricky process: the anaerobic oxidation of methane (AOM). These poorly understood consortia are globally distributed in oceanic sediments above methane hydrates and provide a significant sink for methane by substantially reducing the export of this potent greenhouse gas into the atmosphere. After sequencing the genomes of the purified syntrophic consortia, Pernthaler and co-workers could find all genes responsible for AOM. The scientist also discovered an unexpected diversity in the bacterial partners of this syntrophic association, which may play a role in the performance of AOM. Pernthaler and co-workers also found genes for N2 fixation and demonstrated in lab experiments that the AOM archaea are indeed fixing N2. These results are intriguing, especially since the fixation of N2 is energetically expensive processes and the energy gained by AOM is low. The potential for metabolic versatility combined with the ability to form partnerships with other microorganisms, might be the secret to the successful distribution of this biogeochemically significant group of microorganisms. This work is being published in PNAS, May 13th, 2008, the method has been patented (Pernthaler A, Orphan VJ (2007) US Patent 11/746,374).

More about micro-biology and other topics related to biodiversity can be found in a special edition of the UFZ newsletter to the 9th Conference of the Parties (COP 9) to the Convention on Biological Diversity from 19 to 30 May 2008 in Bonn, Germany.

Publication:

Pernthaler A., Dekas, A.E., Brown C.T., Goffredi S., Embaye T., Orphan V.J. (2008): Diverse syntrophic partnerships from deep-sea methane vents revealed by direct cell capture and metagenomics.
PNAS - Proceedings of the National Academy of Sciences (13. Mai 2008)
Proc. Natl. Acad. Sci. USA, 10.1073/pnas.0711303105
http://www.pnas.org/current.shtml

More information:

Helmholtz Centre for Environmental Research (UFZ)
Dr. Annelie Pernthaler
phone +49 341 235 1377, 1260
Dr. Annelie Pernthaler
www.planetofmicrobes.com

oder über

Helmholtz Centre for Environmental Research
Press office
Tilo Arnhold / Doris Böhme
Telefon: +49 341 235 2278
presse@ufz.de

Further Links

California Institute of Technology:
www.caltech.edu
Press Release: Partnerships of Deep-Sea Methane Scavengers Revealed
mr.caltech.edu/media/Press_Releases/PR13141.html

Anaerobic oxidation of methane (AOM):
http://en.wikipedia.org/wiki/Anaerobic_oxidation_of_methane

Archaea:
http://en.wikipedia.org/wiki/Archaea

Fluorescent in situ hybridization:
http://en.wikipedia.org/wiki/Fluorescent_in_situ_hybridization

The ninth meeting of the Conference of the Parties (COP 9)
www.cbd.int/cop9
www.bmu.de/naturschutz_biologische_vielfalt/un-konferenz_2008

At the Helmholtz Centre for Environmental Research (UFZ) scientists research the causes and consequences of far-reaching environmental changes. They study water resources, biological diversity, the consequences of climate change and adaptation possibilities, environmental and biotechnologies, bio energy, the behaviour of chemicals in the environment and their effect on health, as well as modelling and social science issues. Their guiding research principle is supporting the sustainable use of natural resources and helping to secure these basic requirements of life over the long term under the influence of global change. The UFZ employs 900 people at its sites in Leipzig, Halle and Magdeburg. It is funded by the German government and by the states of Saxony and Saxony-Anhalt.
The Helmholtz Association helps solve major, pressing challenges facing society, science and the economy with top scientific achievements in six research areas: Energy, Earth and Environment, Health, Key Technologies, Structure of Matter, Transport and Space. With 25,700 employees in 15 research centres and an annual budget of around EUR 2.3 billion, the Helmholtz Association is Germany’s largest scientific organisation. Its work follows in the tradition of the great natural scientist Hermann von Helmholtz (1821-1894).