A nitrite-oxidising bacterium constitutively consumes atmospheric hydrogen

Pok Man Leung, Anne Daebeler (Corresponding author), Eleonora Chiri, Iresha Hanchapola, David L Gillett, Ralf B Schittenhelm, Holger Daims (Corresponding author), Chris Greening (Corresponding author)

Publications: Contribution to journalArticlePeer Reviewed

Abstract

Chemolithoautotrophic nitrite-oxidising bacteria (NOB) of the genus Nitrospira contribute to nitrification in diverse natural environments and engineered systems. Nitrospira are thought to be well-adapted to substrate limitation owing to their high affinity for nitrite and capacity to use alternative energy sources. Here, we demonstrate that the canonical nitrite oxidiser Nitrospira moscoviensis oxidises hydrogen (H2) below atmospheric levels using a high-affinity group 2a nickel-iron hydrogenase [Km(app) = 32 nM]. Atmospheric H2 oxidation occurred under both nitrite-replete and nitrite-deplete conditions, suggesting low-potential electrons derived from H2 oxidation promote nitrite-dependent growth and enable survival during nitrite limitation. Proteomic analyses confirmed the hydrogenase was abundant under both conditions and indicated extensive metabolic changes occur to reduce energy expenditure and growth under nitrite-deplete conditions. Thermodynamic modelling revealed that H2 oxidation theoretically generates higher power yield than nitrite oxidation at low substrate concentrations and significantly contributes to growth at elevated nitrite concentrations. Collectively, this study suggests atmospheric H2 oxidation enhances the growth and survival of NOB amid variability of nitrite supply, extends the phenomenon of atmospheric H2 oxidation to an eighth phylum (Nitrospirota), and reveals unexpected new links between the global hydrogen and nitrogen cycles. Long classified as obligate nitrite oxidisers, our findings suggest H2 may primarily support growth and survival of certain NOB in natural environments.

Original languageEnglish
Pages (from-to)2213-2219
Number of pages7
JournalThe ISME Journal
Volume16
Issue number9
DOIs
Publication statusPublished - 1 Sep 2022

Austrian Fields of Science 2012

  • 106022 Microbiology

Keywords

  • Ammonia/metabolism
  • Bacteria
  • Hydrogen/metabolism
  • Nitrification
  • Nitrites/metabolism
  • Oxidation-Reduction
  • Proteomics
  • environmental microbiolgoy
  • microbial ecology

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