Reclamation of coastal wetland to paddy soils alters the role of bacteria and fungi in nitrous oxide emissions: Evidence from a 53-year reclamation chronosequence study

Coastal wetlands are significant sources of nitrous oxide (N2O), a potent greenhouse gas and ozone depleting agent. Land reclamation is known to change N2O emissions from coastal wetlands, but the long-term impacts on N2O sources and emissions are not well-understood. Here, we performed respiration...

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Published inAgriculture, ecosystems & environment Vol. 371; p. 109088
Main Authors Chen, Cheng, Wu, Han, Li, Chuangchuang, Yin, Guoyu, Yin, Tianyu, Pan, Jiongyu, Liang, Xia, Li, Xiaofei, Zheng, Yanling, Hou, Lijun, Liu, Min
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.09.2024
Subjects
agriculture
Bacteria and fungi
chronosequences
Coastal wetland
denitrification
denitrifying microorganisms
environment
fungi
global change
greenhouse gases
Nitrous oxide
ozone
paddies
Penicillium
Reclamation chronosequences
salinity
soil
Trichoderma
wetlands
Reclamation chronosequences
Nitrous oxide
Coastal wetland
Bacteria and fungi
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Abstract Coastal wetlands are significant sources of nitrous oxide (N2O), a potent greenhouse gas and ozone depleting agent. Land reclamation is known to change N2O emissions from coastal wetlands, but the long-term impacts on N2O sources and emissions are not well-understood. Here, we performed respiration inhibition and molecular techniques to dissect the long-term effects of coastal reclamation on bacterial, fungal and overall N2O emissions across a 53-year chronosequence of paddy soils reclaimed from coastal wetlands. Our findings showed that reclamation of coastal wetlands to paddy soils generally promoted N2O emissions in the chronosequences, despite a significant reduction in uncultivated paddy soils. The observed increase in N2O emissions was primarily attributed to an imbalance between N2O production and consumption driven by bacterial denitrifiers. Additionally, reclamation of coastal wetlands to paddy soils shifted N2O emissions from fungal to bacterial predominance in the chronosequences, with denitrification mediated by bacterial denitrifiers dominating bacterial N2O emissions. By integrating the analysis of N2O emission rates with soil physicochemical and microbiological properties, we demonstrated that the reduced salinity following coastal reclamation diminished the relative abundance of key fungal denitrifiers (e.g., Paraconiothyrium, Penicillium and Trichoderma), thus lowering the fungal contribution to N2O emissions. This study provides novel insights into the long-term influences of coastal reclamation on the sources and emissions of N2O, and enhance our knowledge of the underlying mechanisms driving these impacts, thereby contributing to improving future models of N2O emissions from coastal ecosystems under global change. [Display omitted] •Long-term impacts of coastal reclamation on N2O source and emission were explored.•Influences of coastal reclamation on N2O emission depend on reclamation types.•Coastal reclamation shifted N2O emission from fungal to bacterial dominance.•Bacterial denitrifiers mediated denitrification dominated bacterial N2O emission.•Reduction in the abundance of key fungal denitrifiers led to shift in N2O source.
AbstractList Coastal wetlands are significant sources of nitrous oxide (N2O), a potent greenhouse gas and ozone depleting agent. Land reclamation is known to change N2O emissions from coastal wetlands, but the long-term impacts on N2O sources and emissions are not well-understood. Here, we performed respiration inhibition and molecular techniques to dissect the long-term effects of coastal reclamation on bacterial, fungal and overall N2O emissions across a 53-year chronosequence of paddy soils reclaimed from coastal wetlands. Our findings showed that reclamation of coastal wetlands to paddy soils generally promoted N2O emissions in the chronosequences, despite a significant reduction in uncultivated paddy soils. The observed increase in N2O emissions was primarily attributed to an imbalance between N2O production and consumption driven by bacterial denitrifiers. Additionally, reclamation of coastal wetlands to paddy soils shifted N2O emissions from fungal to bacterial predominance in the chronosequences, with denitrification mediated by bacterial denitrifiers dominating bacterial N2O emissions. By integrating the analysis of N2O emission rates with soil physicochemical and microbiological properties, we demonstrated that the reduced salinity following coastal reclamation diminished the relative abundance of key fungal denitrifiers (e.g., Paraconiothyrium, Penicillium and Trichoderma), thus lowering the fungal contribution to N2O emissions. This study provides novel insights into the long-term influences of coastal reclamation on the sources and emissions of N2O, and enhance our knowledge of the underlying mechanisms driving these impacts, thereby contributing to improving future models of N2O emissions from coastal ecosystems under global change. [Display omitted] •Long-term impacts of coastal reclamation on N2O source and emission were explored.•Influences of coastal reclamation on N2O emission depend on reclamation types.•Coastal reclamation shifted N2O emission from fungal to bacterial dominance.•Bacterial denitrifiers mediated denitrification dominated bacterial N2O emission.•Reduction in the abundance of key fungal denitrifiers led to shift in N2O source.
Coastal wetlands are significant sources of nitrous oxide (N₂O), a potent greenhouse gas and ozone depleting agent. Land reclamation is known to change N₂O emissions from coastal wetlands, but the long-term impacts on N₂O sources and emissions are not well-understood. Here, we performed respiration inhibition and molecular techniques to dissect the long-term effects of coastal reclamation on bacterial, fungal and overall N₂O emissions across a 53-year chronosequence of paddy soils reclaimed from coastal wetlands. Our findings showed that reclamation of coastal wetlands to paddy soils generally promoted N₂O emissions in the chronosequences, despite a significant reduction in uncultivated paddy soils. The observed increase in N₂O emissions was primarily attributed to an imbalance between N₂O production and consumption driven by bacterial denitrifiers. Additionally, reclamation of coastal wetlands to paddy soils shifted N₂O emissions from fungal to bacterial predominance in the chronosequences, with denitrification mediated by bacterial denitrifiers dominating bacterial N₂O emissions. By integrating the analysis of N₂O emission rates with soil physicochemical and microbiological properties, we demonstrated that the reduced salinity following coastal reclamation diminished the relative abundance of key fungal denitrifiers (e.g., Paraconiothyrium, Penicillium and Trichoderma), thus lowering the fungal contribution to N₂O emissions. This study provides novel insights into the long-term influences of coastal reclamation on the sources and emissions of N₂O, and enhance our knowledge of the underlying mechanisms driving these impacts, thereby contributing to improving future models of N₂O emissions from coastal ecosystems under global change.
ArticleNumber 109088
Author Yin, Tianyu
Li, Chuangchuang
Liang, Xia
Wu, Han
Li, Xiaofei
Chen, Cheng
Pan, Jiongyu
Yin, Guoyu
Liu, Min
Zheng, Yanling
Hou, Lijun
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  email: mliu@geo.ecnu.edu.cn
  organization: Key Laboratory of Geographic Information Science (Ministry of Education), East China Normal University, Shanghai 200241, China
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crossref_primary_10_1016_j_jhydrol_2024_132170
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Keywords Reclamation chronosequences
Nitrous oxide
Coastal wetland
Bacteria and fungi
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– volume: 179
  year: 2023
  ident: 10.1016/j.agee.2024.109088_bib10
  article-title: Reclamation of tidal flats to paddy soils reshuffles the soil microbiomes along a 53-year reclamation chronosequence: evidence from assembly processes, co-occurrence patterns and multifunctionality
  publication-title: Environ. Int.
  doi: 10.1016/j.envint.2023.108151
– volume: 176
  year: 2023
  ident: 10.1016/j.agee.2024.109088_bib44
  article-title: Grassland degradation-induced declines in soil fungal complexity reduce fungal community stability and ecosystem multifunctionality
  publication-title: Soil Biol. Biochem.
  doi: 10.1016/j.soilbio.2022.108865
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Snippet Coastal wetlands are significant sources of nitrous oxide (N2O), a potent greenhouse gas and ozone depleting agent. Land reclamation is known to change N2O...
Coastal wetlands are significant sources of nitrous oxide (N₂O), a potent greenhouse gas and ozone depleting agent. Land reclamation is known to change N₂O...
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SubjectTerms agriculture
Bacteria and fungi
chronosequences
Coastal wetland
denitrification
denitrifying microorganisms
environment
fungi
global change
greenhouse gases
Nitrous oxide
ozone
paddies
Penicillium
Reclamation chronosequences
salinity
soil
Trichoderma
wetlands
Title Reclamation of coastal wetland to paddy soils alters the role of bacteria and fungi in nitrous oxide emissions: Evidence from a 53-year reclamation chronosequence study
URI https://dx.doi.org/10.1016/j.agee.2024.109088
https://www.proquest.com/docview/3153551834
Volume 371
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