A novel mechanism for dissimilatory nitrate reduction to ammonium in Acididesulfobacillus acetoxydans

The biological route of nitrate reduction has important implications for the bioavailability of nitrogen within ecosystems. Nitrate reduction via nitrite, either to ammonium (ammonification) or to nitrous oxide or dinitrogen (denitrification), determines whether nitrogen is retained within the syste...

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Bibliographic Details
Published in:mSystems 2024-03, Vol.9 (3), p.e0096723-e0096723
Main Authors: Egas, Reinier A, Kurth, Julia M, Boeren, Sjef, Sousa, Diana Z, Welte, Cornelia U, Sánchez-Andrea, Irene
Format: Article
Language:English
Subjects:
acid mine drainage
acidophilic sulfate-reducing bacteria
Ammonia
Ammonification
Ammonium
Ammonium Compounds - metabolism
asrABC
Bacteria - metabolism
Bioavailability
Candidates
Denitrification
DNRA
Ecosystem
Ecosystems
Environmental Microbiology
Enzymes
Experiments
Ferredoxin
Genes
Genomes
Glycerol
Hydroxylamine
Hydroxylamines
Intermediates
Metabolism
Mine drainage
Nitrate reductase
Nitrate reduction
Nitrates
Nitrates - metabolism
Nitric oxide
Nitrite reductase
Nitrite Reductases - metabolism
nitrite reduction
Nitrites
Nitrites - metabolism
Nitrogen
Nitrogen cycle
nitrosative stress
Nitrous oxide
Physiology
Proteomics
Research Article
Sulfate reduction
Sulfates
Sulfite
Sulfite reductase
Transcriptomics
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Summary:The biological route of nitrate reduction has important implications for the bioavailability of nitrogen within ecosystems. Nitrate reduction via nitrite, either to ammonium (ammonification) or to nitrous oxide or dinitrogen (denitrification), determines whether nitrogen is retained within the system or lost as a gas. The acidophilic sulfate-reducing bacterium (aSRB) can perform dissimilatory nitrate reduction to ammonium (DNRA). While encoding a Nar-type nitrate reductase, lacks recognized nitrite reductase genes. In this study, was cultivated under conditions conducive to DNRA. During cultivations, we monitored the production of potential nitrogen intermediates (nitrate, nitrite, nitric oxide, hydroxylamine, and ammonium). Resting cell experiments were performed with nitrate, nitrite, and hydroxylamine to confirm their reduction to ammonium, and formed intermediates were tracked. To identify the enzymes involved in DNRA, comparative transcriptomics and proteomics were performed with growing under nitrate- and sulfate-reducing conditions. Nitrite is likely reduced to ammonia by the previously undescribed nitrite reductase activity of the NADH-linked sulfite reductase AsrABC, or by a putatively ferredoxin-dependent homolog of the nitrite reductase NirA (DEACI_1836), or both. We identified enzymes and intermediates not previously associated with DNRA and nitrosative stress in aSRB. This increases our knowledge about the metabolism of this type of bacteria and helps the interpretation of (meta)genome data from various ecosystems on their DNRA potential and the nitrogen cycle.IMPORTANCENitrogen is crucial to any ecosystem, and its bioavailability depends on microbial nitrogen-transforming reactions. Over the recent years, various new nitrogen-transforming reactions and pathways have been identified, expanding our view on the nitrogen cycle and metabolic versatility. In this study, we elucidate a novel mechanism employed by , an acidophilic sulfate-reducing bacterium, to reduce nitrate to ammonium. This finding underscores the diverse physiological nature of dissimilatory reduction to ammonium (DNRA). was isolated from acid mine drainage, an extremely acidic environment where nitrogen metabolism is poorly studied. Our findings will contribute to understanding DNRA potential and variations in extremely acidic environments.
ISSN:2379-5077
2379-5077
DOI:10.1128/msystems.00967-23