Abstract
AbstractMethanotrophic bacteria mitigate methane (CH4) emissions from natural environments. Although aerobic methanotrophs are considered strict aerobes, they are often highly abundant in extremely hypoxic and even anoxic environments. Despite the presence of denitrification genes, it remains to be verified whether denitrification contributes to their growth. Here, we revealed that two acidophilic methanotrophs encoding N2O reductase (clade I and type II nosZ, respectively):Methylocella tundraeT4 andMethylacidiphilum caldifontisIT6, respired N2O and grew anaerobically on diverse non-methane substrates, including methanol, C-C substrates, and hydrogen. However, NO3−and NO2−could be reduced during methanol oxidation inMethylocella tundraeT4 andMethylocella silvestrisBL2 without significantly increasing cell biomass. The lack of growth on methanol + NO3−or NO2−was likely due to the production of toxic reactive nitrogen species and C1 metabolites. However, the oxidation of pyruvate, a C3 electron donor, combined with NO3−or NO2−reduction resulted in anaerobic growth ofMethylocella tundraeT4 andMethylocella silvestrisBL2. In the extreme acidophile,Methylacidiphilum caldifontisIT6, N2O respiration supported cell growth at an extremely acidic pH of 2.0. InMethylocella tundraeT4, simultaneous consumption of N2O and CH4was observed in suboxic conditions, both in microrespirometry and growth experiments, indicating the robustness of its N2O reductase activity in the presence of O2. Furthermore, CH4oxidation per O2reduced in O2-limiting conditions increased when N2O was added, indicating that cells of T4 can direct more O2towards methane monooxygenase when respiring N2O as a terminal electron acceptor. Upregulation ofnosZand distinct repertories of methanol dehydrogenase-encoding genes (XoxF- and MxaFI-type) inMethylocella tundraeT4 cells grown anaerobically on methanol with N2O as the sole electron acceptor indicated adaptation mechanisms to anoxia. Our findings demonstrate that some methanotrophs can respire N2O independently or in tandem with O2, significantly expanding their potential ecological niche and paving the way for enhanced growth and survival in dynamic environments. This metabolic capability has application potential for simultaneously mitigating the emissions of the key greenhouse gases, CO2, CH4,and N2O, from natural and engineered environments.
Publisher
Cold Spring Harbor Laboratory
Reference139 articles.
1. IPCC. Summary for Policymakers. In: Climate Change 2021 – The Physical Science Basis: Working Group I Contribution to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change (ed Intergovernmental Panel on Climate C). Cambridge University Press (2023).
2. Forster P , et al. The Earth’s Energy Budget, Climate Feedbacks and Climate Sensitivity. In: Climate Change 2021: The Physical Science Basis: Working Group I Contribution to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change (eds Masson-Delmotte, et al.). Cambridge University Press United Kingdom and New York, NY, USA (2023).
3. Prinn RG , et al. Evidence for variability of atmospheric hydroxyl radicals over the past quarter century. Geophys Res Lett 32, (2005).
4. Szopa S , et al. Short-Lived Climate Forcers. In: Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change (eds Masson-Delmotte V, et al.). Cambridge University Press (2021).
5. Measuring and modeling the lifetime of nitrous oxide including its variability;J Geophys Res Atmos,2015