Metagenomics and Stable Isotopes Uncover the Augmented Sulfide-Driven Autotrophic Denitrification in a Seasonally Hypoxic, Sulfate-Abundant Reservoir

The mechanism governing sulfur cycling in nitrate reduction within sulfate-rich reservoirs during seasonal hypoxic conditions remains poorly understood. This study employs nitrogen and oxygen isotope fractionation in nitrate, along with metagenomic sequencing to elucidate the intricacies of the coup...

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Published in:Environmental science & technology 2024-08, Vol.58 (32), p.14225-14236
Main Authors: Yang, Mengdi, Luo, Qianli, Fan, Zhongya, Zeng, Fantang, Huang, Lu, Ding, Shiyuan, Cui, Gaoyang, Li, Dongli, Wei, Gangjian, Liu, Cong-Qiang, Li, Xiao-Dong
Format: Article
Language:English
Subjects:
Bacteria
Biogeochemical Cycling
Coexistence
Denitrification
Fractionation
Hypoxia
Isotope fractionation
Isotopes
Metagenomics
Nitrate reduction
Nitrates
Nitrogen
Nitrogen cycle
Oxidation
Oxygen isotopes
Reservoirs
Stable isotopes
Stratified water
Sulfate reduction
Sulfates
Sulfides
Sulfur
Sulfur oxidation
Water bodies
Water circulation
Water column
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Summary:The mechanism governing sulfur cycling in nitrate reduction within sulfate-rich reservoirs during seasonal hypoxic conditions remains poorly understood. This study employs nitrogen and oxygen isotope fractionation in nitrate, along with metagenomic sequencing to elucidate the intricacies of the coupled sulfur oxidation and nitrate reduction process in the water column. In the Aha reservoir, a typical seasonally stratified water body, we observed the coexistence of denitrification, bacterial sulfide oxidation, and bacterial sulfate reduction in hypoxic conditions. This is substantiated by the presence of abundant N/S-related genes (nosZ and aprAB/dsrAB) and fluctuations in N/S species. The lower 15εNO3/18εNO3 ratio (0.60) observed in this study, compared to heterotrophic denitrification, strongly supports the occurrence of sulfur-driven denitrification. Furthermore, we found a robust positive correlation between the metabolic potential of bacterial sulfide oxidation and denitrification (p < 0.05), emphasizing the role of sulfide produced via sulfate reduction in enhancing denitrification. Sulfide-driven denitrification relied on ∑S2– as the primary electron donor preferentially oxidized by denitrification. The pivotal genus, Sulfuritalea, emerged as a central player in both denitrification and sulfide oxidation processes in hypoxic water bodies. Our study provides compelling evidence that sulfides assume a critical role in regulating denitrification in hypoxic water within an ecosystem where their contribution to the overall nitrogen cycle was previously underestimated.
ISSN:0013-936X
1520-5851
1520-5851
DOI:10.1021/acs.est.4c00248