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With DNA from just four cells, Danish researchers reveal how some of the world’s most abundant organisms play a key role in carbon cycling in the seabed.
Single-celled archaea are invisible to the naked eye, and even when using a microscope, great care must be taken to observe them. An international team of researchers led by the Center for Geomicrobiology, Aarhus University, has nevertheless succeeded in retrieving four archaeal cells from seabed mud and mapping the genome of each one.
“Until now, nobody knew how these widespread mud-dwelling archaea actually live. Mapping the genome from the four archaeal cells shows they all have genes that enable them to live on protein degradation,” says Postdoctoral Fellow Dr. Dorthe Groth Petersen, who is a part of the research group publishing the ground-breaking results today in the renowned journal Nature.
Scientists previously thought that proteins were only broken down in the sea by bacteria, but archaea have now turned out to be important new key organisms in protein degradation in the seabed. Proteins actually make up a large part of the organic matter in the seabed and – since the seabed has the world’s largest deposit of organic carbon – archaea thus appear to play an important and previously unknown role in the global carbon cycle.
Like a grain of sand on the beach
Archaea are some of the most abundant organisms in the world, but very few people have ever heard of them. They were originally discovered in extreme environments such as hot springs and other special environments like cow stomachs and rice paddies, where they form methane. In recent years, however, researchers have realised that archaea make up a large part of the microorganisms in the seabed, and that the seabed is also the habitat of the majority of the world’s microorganisms.
“A realistic estimate is that archaea are the group of organisms with the most individuals in the world. In fact, there are more archaea than there are grains of sand on the beaches of the whole world. If you bury your toes right down in the mud in the seabed, you’ll be in touch with billions of archaea,” says Professor Bo Barker Jørgensen, Director of the Center for Geomicrobiology.
New technology links function and identity
This is the first time that scientists have succeeded in classifying archaeal cells in a mud sample from the seabed and subsequently analysing the genome of the cells, thereby revealing what the organisms are and what they live on.
“At present, we can’t culture these archaea or store them in the laboratory, so this rules out the physiological tests usually carried out by the microbiologists. We’ve therefore worked with cell extraction, cell sorting, and subsequent mapping of the individual cell’s combined genetic information – that’s to say its genome. This is a new approach that can reveal both a cell’s identity and its lifestyle,” says Professor of Microbiology Andreas Schramm, affiliated with the Center for Geomicrobiology.
Dr. Michael Richter from Ribocon has developed the Software to analyse the genomic data and was involved in this project, too. ”Raw genomic data alone are not enough. These data have to be translated like a book in a foreign language into words, sentences, punctuation marks, chapters and sections in order to identify the genes and their regulators. This can be accomplished with our software. Researcher can reconstruct complete cellular pathways and transportion processes in the computer.”
The method opens up a new world of knowledge for microbiologists, who can now study an individual microorganism just as zoologists study an individual mouse. Microbiologists have been hoping for this for a long time. Until now, they have only been familiar with the life processes of less than 1% of the world’s microorganisms – those they can culture in a laboratory. The new method provides opportunities for studying the remaining 99% directly from nature, without being dependent on culturing the microorganisms in the laboratory. In future, this method will no doubt reveal new, unknown functions of microorganisms from many different environments.
For more information please contact
Professor Andreas Schramm, Microbiology and Center for Geomicrobiology, Department of Bioscience, Aarhus University, +45 8715 6541/6020 2659, andreas.schramm@biology.au.dkmailto:bo.barker@biology.au.dk
Dr. Michael Richter, Ribocon, Fahrenheitstraße 1, 28359 Bremen.
+49 421 2487053 mrichter@ribocon.com
or the press officers at the Max Planck Institiute for Marine Microbiology
Dr. Manfred Schlösser mschloes@mpi-bremen.de +49 (0) 421 2028 704
Dr. Rita Dunker rdunker@mpi-bremen.de +49 (0) 421 2028 856
Original publication
Predominant archaea in marine sediments degrade detrital proteins
Karen G. Lloyd, Lars Schreiber, Dorthe G. Petersen, Kasper Kjeldsen, Mark A.
Lever, Andrew D. Steen, Ramunas Stepanauskas, Michael Richter, Sara Kleindienst,
Sabine Lenk, Andreas Schramm, Bo B. Jørgensen
Nature 2013, 10.1038/nature12033
Institutes
Center for Geomicrobiology, Aarhus University, Denmark (geomicrobiology.au.dk)
University of Tennessee, Knoxville, TN, USA (www.utk.edu)
Bigelow Laboratory for Ocean Sciences, East Boothbay, Maine, USA (www.bigelow.org/)
Max Plank Institute for Marine Microbiology, Bremen, Germany www.mpi-bremen.de
Ribocon GmbH, Bremen (www.ribocon.com)
http://www.mpi-bremen.de Web site of the Max Planck Institute for Marine Microbiology
The bore sample has just been brought up from the bottom of the Bay of Aarhus and is being cut up. T ...
Quelle: Bo Barker Jørgensen
The computer screenshot of the program JCoast shows the reconstructed gene structure.
Quelle: Michael Richter
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The bore sample has just been brought up from the bottom of the Bay of Aarhus and is being cut up. T ...
Quelle: Bo Barker Jørgensen
The computer screenshot of the program JCoast shows the reconstructed gene structure.
Quelle: Michael Richter
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