Biological Nitrogen Removal Database

Uncultured bacterium

• Phylum : nan
• Class : nan
• Order : nan
• Family : nan
• Genus : nan

Rice paddy soil

Nitrite reductase 

• Encoding Gene:nrfA
• DNA Size：233 bp
• Nucleotide FASTA sequence： Link

• UniProt I.D: A0A6F8WZI3

• Pro_GenBank I.D： BCB63251.1

• Length：77 aa
• Protein FASTA_sequence: Link

• Reference：Nojiri et al., 2020
• Title：Dissimilatory Nitrate Reduction to Ammonium and Responsible Microbes in Japanese Rice Paddy Soil
• Pubmed ID：33028782
• Pubmed link： Link

• Full research link： Link

• Abstract：Nitrification–denitrification processes in the nitrogen cycle have been extensively examined in rice paddy soils. Nitrate is generally depleted in the reduced soil layer below the thin oxidized layer at the surface, and this may be attributed to high denitrification activity. In the present study, we investigated dissimilatory nitrate reduction to ammonium (DNRA), which competes with denitrification for nitrate, in order to challenge the conventional view of nitrogen cycling in paddy soils. We performed paddy soil microcosm experiments using 15N tracer analyses to assess DNRA and denitrification rates and conducted clone library analyses of transcripts of nitrite reductase genes (nrfA, nirS, and nirK) in order to identify the microbial populations carrying out these processes. The results obtained showed that DNRA occurred to a similar extent to denitrification and appeared to be enhanced by a nitrate limitation relative to organic carbon. We also demonstrated that different microbial taxa were responsible for these distinct processes. Based on these results and previous field observations, nitrate produced by nitrification within the surface oxidized layer may be reduced not only to gaseous N2 via denitrification, but also to NH4+ via DNRA, within the reduced layer. The present results also indicate that DNRA reduces N loss through denitrification and nitrate leaching and provides ammonium to rice roots in rice paddy fields.