Abstract
BackgroundA wealth of microbial eukaryotes is adapted to life in oxygen-deficient marine environments. Evidence is accumulating that some of these eukaryotes survive anoxia by employing dissimilatory nitrate reduction, a strategy that otherwise is widespread in prokaryotes. Here, we report on the anaerobic nitrate metabolism of the fungus Aspergillus terreus (isolate An-4) that was obtained from sediment in the seasonal oxygen minimum zone in the Arabian Sea, a globally important site of oceanic nitrogen loss and nitrous oxide emission.ResultsAxenic incubations of An-4 in the presence and absence of oxygen and nitrate revealed that this fungal isolate is capable of dissimilatory nitrate reduction to ammonium under anoxic conditions. A 15N-labeling experiment proved that An-4 produced and excreted ammonium through nitrate reduction at a rate of up to 175 nmol 15NH4+ g-1 protein h-1. The products of dissimilatory nitrate reduction were ammonium (83%), nitrous oxide (15.5%), and nitrite (1.5%), while dinitrogen production was not observed. The process led to substantial cellular ATP production and biomass growth and also occurred when ammonium was added to suppress nitrate assimilation, stressing the dissimilatory nature of nitrate reduction. Interestingly, An-4 used intracellular nitrate stores (up to 6–8 μmol NO3- g-1 protein) for dissimilatory nitrate reduction.ConclusionsOur findings expand the short list of microbial eukaryotes that store nitrate intracellularly and carry out dissimilatory nitrate reduction when oxygen is absent. In the currently spreading oxygen-deficient zones in the ocean, an as yet unexplored diversity of fungi may recycle nitrate to ammonium and nitrite, the substrates of the major nitrogen loss process anaerobic ammonium oxidation, and the potent greenhouse gas nitrous oxide.
Highlights
A wealth of microbial eukaryotes is adapted to life in oxygen-deficient marine environments
Nitrate (NO-3) serves as both a nitrogen source for assimilation and an electron acceptor for dissimilatory processes when oxygen (O2) is deficient. The latter scenario is ubiquitously encountered in anoxic sediment layers, and prevails in the water bodies of oxygen minimum zones (OMZs) of the world’s oceans [1]
A large number of fungal species, mainly belonging to Ascomycota, are capable of “ammonia fermentation”, a form of NO−3 reduction to ammonium NHþ coupled to the fermentation of organic compounds [11]
Summary
A wealth of microbial eukaryotes is adapted to life in oxygen-deficient marine environments. We report on the anaerobic nitrate metabolism of the fungus Aspergillus terreus (isolate An-4) that was obtained from sediment in the seasonal oxygen minimum zone in the Arabian Sea, a globally important site of oceanic nitrogen loss and nitrous oxide emission. Nitrate (NO-3) serves as both a nitrogen source for assimilation and an electron acceptor for dissimilatory processes when oxygen (O2) is deficient. The latter scenario is ubiquitously encountered in anoxic sediment layers, and prevails in the water bodies of oxygen minimum zones (OMZs) of the world’s oceans [1]. Nitrate is sequentially reduced to di nitrogen NO−3 →NO−2 →NO→N2 O→N2 , in dissimilatory nitrate reduction to ammonium (DNRA), nitrate is. A large number of fungal species, mainly belonging to Ascomycota, are capable of “ammonia fermentation”, a form of NO−3 reduction to ammonium NHþ coupled to the fermentation of organic compounds [11]
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