Biological Nitrogen Removal Database

A manually curated data resource for microbial nitrogen removal


Detailed information

Microorganism

Bacterium

Taxonomy

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

Isolation Source

Sub-seafloor sulfide deposits

Enzyme Name

Hydroxylamine oxidoreductase

  • Encoding Gene:hao1
  • DNA Size:3501 bp
  • Nucleotide FASTA sequence: Link

  • UniProt I.D: A0A2H6EMS9

Protein Information

  • Pro_GenBank I.D: GBD90790.1

  • Length:414 aa
  • Protein FASTA_sequence: Link

Information about Article

  • Reference:Kato et al., 2018
  • Title:Genome-enabled metabolic reconstruction of dominant chemosynthetic colonizers in deep-sea massive sulfide deposits
  • Pubmed ID:29322618
  • Pubmed link: Link

  • Full research link: Link

  • Abstract:Deep-sea massive sulfide deposits remaining after ceasing of hydrothermal activity potentially provide energy for a chemosynthetic ecosystem in the dark, cold marine environments. Although yet-uncultivated bacteria in the phylum Nitrospirae and the class Deltaproteobacteria are known to dominate the microbial communities of sulfide deposits at and below the seafloor, their metabolic capabilities remain largely elusive. Here, we reveal the metabolic potential of these yet-uncultivated bacteria in hydrothermally inactive sulfide deposits collected at the Southern Mariana Trough by seafloor drilling. Near-complete genomes of the predominant bacterial members were recovered from shotgun metagenomic sequences. The genomic capabilities for CO2 and N2 fixation suggest that these bacteria are primary producers in the microbial ecosystem. Their genomes also encode versatile chemolithotrophic energy metabolisms, such as the oxidation of H2 , sulfide and intermediate sulfur species including thiosulfate, all of which can be supplied by chemical reactions between seawater and metal sulfides. Notably, the presence of genes involved in thiosulfate oxidation in Nitrospirae and Deltaproteobacteria genomes is unusual. Our study strongly support the presence of a chemosynthetic ecosystem fuelled by the Earth's internal energy in the deep-sea massive sulfide deposits, and illustrates the unexpected metabolic capability of known bacterial taxonomic groups.