Deep sub-seafloor prokaryotes stimulated at interfaces over geological time

The sub-seafloor biosphere is the largest prokaryotic habitat on Earth but also a habitat with the lowest metabolic rates. Modelled activity rates are very low, indicating that most prokaryotes may be inactive or have extraordinarily slow metabolism. Here we present results from two Pacific Ocean si...

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Bibliographic Details
Published in:Nature 2005-07, Vol.436 (7049), p.390-394
Main Authors: Parkes, R. John, Webster, Gordon, Cragg, Barry A, Weightman, Andrew J, Newberry, Carole J, Ferdelman, Timothy G, Kallmeyer, Jens, Jørgensen, Bo B, Aiello, Ivano W, Fry, John C
Format: Article
Language:English
Subjects:
Archaea - genetics
Archaea - isolation & purification
Bacteria - genetics
Bacteria - isolation & purification
Biodiversity
Biosphere
Colony Count, Microbial
Diatoms - isolation & purification
DNA - analysis
DNA - chemistry
DNA - genetics
DNA - isolation & purification
Earth sciences
Earth, ocean, space
Exact sciences and technology
Geochemistry
Geologic Sediments - microbiology
Geological time
Habitats
Humanities and Social Sciences
Invertebrate paleontology
letter
Marine
Metabolism
Methane - analysis
Molecular Weight
multidisciplinary
Ocean floor
Pacific Ocean
Paleontology
Peru
Prokaryotic Cells - classification
Prokaryotic Cells - cytology
Prokaryotic Cells - metabolism
Science
Science (multidisciplinary)
Seawater - microbiology
Sediments
Sequence Analysis, DNA
Sulfates - analysis
Time Factors
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Summary:The sub-seafloor biosphere is the largest prokaryotic habitat on Earth but also a habitat with the lowest metabolic rates. Modelled activity rates are very low, indicating that most prokaryotes may be inactive or have extraordinarily slow metabolism. Here we present results from two Pacific Ocean sites, margin and open ocean, both of which have deep, subsurface stimulation of prokaryotic processes associated with geochemical and/or sedimentary interfaces. At 90 m depth in the margin site, stimulation was such that prokaryote numbers were higher (about 13-fold) and activity rates higher than or similar to near-surface values. Analysis of high-molecular-mass DNA confirmed the presence of viable prokaryotes and showed changes in biodiversity with depth that were coupled to geochemistry, including a marked community change at the 90-m interface. At the open ocean site, increases in numbers of prokaryotes at depth were more restricted but also corresponded to increased activity; however, this time they were associated with repeating layers of diatom-rich sediments (about 9 Myr old). These results show that deep sedimentary prokaryotes can have high activity, have changing diversity associated with interfaces and are active over geological timescales.
ISSN:0028-0836
1476-4687
DOI:10.1038/nature03796