Autotrophic ammonia oxidation by soil thaumarchaea

Nitrification plays a central role in the global nitrogen cycle and is responsible for significant losses of nitrogen fertilizer, atmospheric pollution by the greenhouse gas nitrous oxide, and nitrate pollution of groundwaters. Ammonia oxidation, the first step in nitrification, was thought to be pe...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2010-10, Vol.107 (40), p.17240-17245
Main Authors: Zhang, Li-Mei, Offre, Pierre R., He, Ji-Zheng, Verhamme, Daniel T., Nicol, Graeme W., Prosser, James I.
Format: Article
Language:English
Subjects:
Acid soils
Agricultural soils
Agrology
Ammonia
Ammonia - metabolism
Archaea
Archaea - genetics
Archaea - growth & development
Archaea - metabolism
Autotrophic Processes - physiology
Bacteria
Biological Sciences
DNA, Archaeal - genetics
DNA, Archaeal - metabolism
Genes, Archaeal
Genes, Bacterial
Greenhouse gases
Isotope Labeling
Isotopes
Microcosms
Molecular Sequence Data
Nitric oxide
Nitrification
Nitrogen - metabolism
Oxidation
Oxidation-Reduction
Oxidizers
Oxidoreductases - genetics
Oxidoreductases - metabolism
Soil Microbiology
Soils
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Summary:Nitrification plays a central role in the global nitrogen cycle and is responsible for significant losses of nitrogen fertilizer, atmospheric pollution by the greenhouse gas nitrous oxide, and nitrate pollution of groundwaters. Ammonia oxidation, the first step in nitrification, was thought to be performed by autotrophic bacteria until the recent discovery of archaeal ammonia oxidizers. Autotrophic archaeal ammonia oxidizers have been cultivated from marine and thermal spring environments, but the relative importance of bacteria and archaea in soil nitrification is unclear and it is believed that soil archaeal ammonia oxidizers may use organic carbon, rather than growing autotrophically. In this soil microcosm study, stable isotope probing was used to demonstrate incorporation of ¹³C-enriched carbon dioxide into the genomes of thaumarchaea possessing two functional genes: amoA, encoding a subunit of ammonia monooxygenase that catalyses the first step in ammonia oxidation; and hcd, a key gene in the autotrophic 3-hydroxypropionate/4-hydroxybutyrate cycle, which has been found so far only in archaea. Nitrification was accompanied by increases in archaeal amoA gene abundance and changes in amoA gene diversity, but no change was observed in bacterial amoA genes. Archaeal, but not bacterial, amoA genes were also detected in ¹³C-labeled DNA, demonstrating inorganic CO₂ fixation by archaeal, but not bacterial, ammonia oxidizers. Autotrophic archaeal ammonia oxidation was further supported by coordinate increases in amoA and hcd gene abundance in ¹³C-labeled DNA. The results therefore provide direct evidence for a role for archaea in soil ammonia oxidation and demonstrate autotrophic growth of ammonia oxidizing archaea in soil.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1004947107