Versatile nitrate-respiring heterotrophs are previously concealed contributors to sulfur cycle

Bo Shao; Yuan-Guo Xie; Long Zhang; Yang Ruan; Bin Liang; Ruochen Zhang; Xijun Xu; Wei Wang; Zhengda Lin; Xuanyuan Pei; Xueting Wang; Lei Zhao; Xu Zhou; Xiaohui Wu; Defeng Xing; Aijie Wang; Duu-Jong Lee; Nanqi Ren; Donald E. Canfield; Brian P. Hedlund; Zheng-Shuang Hua; Chuan Chen

doi:10.1038/s41467-025-56588-1

Versatile nitrate-respiring heterotrophs are previously concealed contributors to sulfur cycle

Bo Shao, Yuan-Guo Xie, Long Zhang, Yang Ruan, Bin Liang, Ruochen Zhang, Xijun Xu, Wei Wang, Zhengda Lin, Xuanyuan Pei, Xueting Wang, Lei Zhao, Xu Zhou, Xiaohui Wu, Defeng Xing, Aijie Wang, Duu-Jong Lee, Nanqi Ren, Donald E. Canfield, Brian P. HedlundZheng-Shuang Hua^*, Chuan Chen^*

^*Corresponding author for this work

Department of Mechanical Engineering

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

18 Citations (Scopus)

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Abstract

Heterotrophic denitrifiers play crucial roles in global carbon and nitrogen cycling. However, their inability to oxidize sulfide renders them vulnerable to this toxic molecule, which inhibits the key enzymatic reaction responsible for reducing nitrous oxide (N₂O), thereby raising greenhouse gas emissions. Here, we applied microcosm incubations, community-isotope-corrected DNA stable-isotope probing, and metagenomics to characterize a cohort of heterotrophic denitrifiers in estuarine sediments that thrive by coupling sulfur oxidation with denitrification through chemolithoheterotrophic metabolism. Remarkably, ecophysiology experiments from enrichments demonstrate that such heterotrophs expedite denitrification with sulfur acting as alternative electron sources and substantially curtail N₂O emissions in both organic-rich and organic-limited environments. Their flexible, non-sulfur-dependent physiology may confer competitive advantages over conventional heterotrophic denitrifiers in detoxifying sulfide, adapting to organic matter fluctuations, and mitigating greenhouse gas emissions. Our study provides insights into the ecological role of heterotrophic denitrifiers in microbial communities with implications for sulfur cycling and climate change. © The Author(s) 2025.

Original language	English
Article number	1202
Journal	Nature Communications
Volume	16
Online published	31 Jan 2025
DOIs	https://doi.org/10.1038/s41467-025-56588-1
Publication status	Published - 2025

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Shao, B., Xie, Y.-G., Zhang, L., Ruan, Y., Liang, B., Zhang, R., Xu, X., Wang, W., Lin, Z., Pei, X., Wang, X., Zhao, L., Zhou, X., Wu, X., Xing, D., Wang, A., Lee, D.-J., Ren, N., Canfield, D. E., ... Chen, C. (2025). Versatile nitrate-respiring heterotrophs are previously concealed contributors to sulfur cycle. Nature Communications, 16, Article 1202. https://doi.org/10.1038/s41467-025-56588-1

@article{c200784740964d75a056937efcc1ac29,

title = "Versatile nitrate-respiring heterotrophs are previously concealed contributors to sulfur cycle",

abstract = "Heterotrophic denitrifiers play crucial roles in global carbon and nitrogen cycling. However, their inability to oxidize sulfide renders them vulnerable to this toxic molecule, which inhibits the key enzymatic reaction responsible for reducing nitrous oxide (N2O), thereby raising greenhouse gas emissions. Here, we applied microcosm incubations, community-isotope-corrected DNA stable-isotope probing, and metagenomics to characterize a cohort of heterotrophic denitrifiers in estuarine sediments that thrive by coupling sulfur oxidation with denitrification through chemolithoheterotrophic metabolism. Remarkably, ecophysiology experiments from enrichments demonstrate that such heterotrophs expedite denitrification with sulfur acting as alternative electron sources and substantially curtail N2O emissions in both organic-rich and organic-limited environments. Their flexible, non-sulfur-dependent physiology may confer competitive advantages over conventional heterotrophic denitrifiers in detoxifying sulfide, adapting to organic matter fluctuations, and mitigating greenhouse gas emissions. Our study provides insights into the ecological role of heterotrophic denitrifiers in microbial communities with implications for sulfur cycling and climate change. {\textcopyright} The Author(s) 2025.",

author = "Bo Shao and Yuan-Guo Xie and Long Zhang and Yang Ruan and Bin Liang and Ruochen Zhang and Xijun Xu and Wei Wang and Zhengda Lin and Xuanyuan Pei and Xueting Wang and Lei Zhao and Xu Zhou and Xiaohui Wu and Defeng Xing and Aijie Wang and Duu-Jong Lee and Nanqi Ren and Canfield, {Donald E.} and Hedlund, {Brian P.} and Zheng-Shuang Hua and Chuan Chen",

year = "2025",

doi = "10.1038/s41467-025-56588-1",

language = "English",

volume = "16",

journal = "Nature Communications",

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Shao, B, Xie, Y-G, Zhang, L, Ruan, Y, Liang, B, Zhang, R, Xu, X, Wang, W, Lin, Z, Pei, X, Wang, X, Zhao, L, Zhou, X, Wu, X, Xing, D, Wang, A, Lee, D-J, Ren, N, Canfield, DE, Hedlund, BP, Hua, Z-S & Chen, C 2025, 'Versatile nitrate-respiring heterotrophs are previously concealed contributors to sulfur cycle', Nature Communications, vol. 16, 1202. https://doi.org/10.1038/s41467-025-56588-1

TY - JOUR

T1 - Versatile nitrate-respiring heterotrophs are previously concealed contributors to sulfur cycle

AU - Shao, Bo

AU - Xie, Yuan-Guo

AU - Zhang, Long

AU - Ruan, Yang

AU - Liang, Bin

AU - Zhang, Ruochen

AU - Xu, Xijun

AU - Wang, Wei

AU - Lin, Zhengda

AU - Pei, Xuanyuan

AU - Wang, Xueting

AU - Zhao, Lei

AU - Zhou, Xu

AU - Wu, Xiaohui

AU - Xing, Defeng

AU - Wang, Aijie

AU - Lee, Duu-Jong

AU - Ren, Nanqi

AU - Canfield, Donald E.

AU - Hedlund, Brian P.

AU - Hua, Zheng-Shuang

AU - Chen, Chuan

PY - 2025

Y1 - 2025

N2 - Heterotrophic denitrifiers play crucial roles in global carbon and nitrogen cycling. However, their inability to oxidize sulfide renders them vulnerable to this toxic molecule, which inhibits the key enzymatic reaction responsible for reducing nitrous oxide (N2O), thereby raising greenhouse gas emissions. Here, we applied microcosm incubations, community-isotope-corrected DNA stable-isotope probing, and metagenomics to characterize a cohort of heterotrophic denitrifiers in estuarine sediments that thrive by coupling sulfur oxidation with denitrification through chemolithoheterotrophic metabolism. Remarkably, ecophysiology experiments from enrichments demonstrate that such heterotrophs expedite denitrification with sulfur acting as alternative electron sources and substantially curtail N2O emissions in both organic-rich and organic-limited environments. Their flexible, non-sulfur-dependent physiology may confer competitive advantages over conventional heterotrophic denitrifiers in detoxifying sulfide, adapting to organic matter fluctuations, and mitigating greenhouse gas emissions. Our study provides insights into the ecological role of heterotrophic denitrifiers in microbial communities with implications for sulfur cycling and climate change. © The Author(s) 2025.

AB - Heterotrophic denitrifiers play crucial roles in global carbon and nitrogen cycling. However, their inability to oxidize sulfide renders them vulnerable to this toxic molecule, which inhibits the key enzymatic reaction responsible for reducing nitrous oxide (N2O), thereby raising greenhouse gas emissions. Here, we applied microcosm incubations, community-isotope-corrected DNA stable-isotope probing, and metagenomics to characterize a cohort of heterotrophic denitrifiers in estuarine sediments that thrive by coupling sulfur oxidation with denitrification through chemolithoheterotrophic metabolism. Remarkably, ecophysiology experiments from enrichments demonstrate that such heterotrophs expedite denitrification with sulfur acting as alternative electron sources and substantially curtail N2O emissions in both organic-rich and organic-limited environments. Their flexible, non-sulfur-dependent physiology may confer competitive advantages over conventional heterotrophic denitrifiers in detoxifying sulfide, adapting to organic matter fluctuations, and mitigating greenhouse gas emissions. Our study provides insights into the ecological role of heterotrophic denitrifiers in microbial communities with implications for sulfur cycling and climate change. © The Author(s) 2025.

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U2 - 10.1038/s41467-025-56588-1

DO - 10.1038/s41467-025-56588-1

M3 - RGC 21 - Publication in refereed journal

C2 - 39885140

SN - 2041-1723

VL - 16

JO - Nature Communications

JF - Nature Communications

M1 - 1202

ER -

Versatile nitrate-respiring heterotrophs are previously concealed contributors to sulfur cycle

Abstract

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