Ozone strengthens the ex vivo but weakens the in vivo pathway of the microbial carbon pump in poplar plantations

Zheng, Haifeng; Vesterdal, Lars; Agathokleous, Evgenios; Yuan, Xiangyang; Yuan, Mingyue; Xu, Yansen; Heděnec, Petr; Shang, Bo; Feng, Zhaozhong; Rousk, Johannes

Ozone strengthens the ex vivo but weakens the in vivo pathway of the microbial carbon pump in poplar plantations

Mark

Zheng, Haifeng ^LU ; Vesterdal, Lars ; Agathokleous, Evgenios ; Yuan, Xiangyang ; Yuan, Mingyue ^LU ; Xu, Yansen ; Heděnec, Petr ; Shang, Bo ; Feng, Zhaozhong and Rousk, Johannes ^LU

(2024) In Soil Biology and Biochemistry 198.

Abstract: Elevated ozone (eO₃) and atmospheric nitrogen (N) deposition are important climate change components that can affect plant growth and plant-soil-microbe interactions. However, the understanding of how eO₃ and its interaction with N deposition affect soil microbially mediated carbon (C) cycling and the fate of soil C stocks is limited. This study aimed to test how eO₃ and N deposition affected soil microbial metrics (i.e., respiration, enzyme activities, biomass, necromass, and community composition) and resulting soil organic C (SOC) fractions in the rhizosphere of poplar plantations with different sensitivity to O₃. Exposure to O₃ and/or N deposition for four years was conducted... (More); Elevated ozone (eO₃) and atmospheric nitrogen (N) deposition are important climate change components that can affect plant growth and plant-soil-microbe interactions. However, the understanding of how eO₃ and its interaction with N deposition affect soil microbially mediated carbon (C) cycling and the fate of soil C stocks is limited. This study aimed to test how eO₃ and N deposition affected soil microbial metrics (i.e., respiration, enzyme activities, biomass, necromass, and community composition) and resulting soil organic C (SOC) fractions in the rhizosphere of poplar plantations with different sensitivity to O₃. Exposure to O₃ and/or N deposition for four years was conducted within a free-air O₃ concentration-enrichment facility. Elevated O₃ reduced soil microbial respiration and biomass C but enhanced the enzymatic acquisition of C (i.e., potential soil hydrolase and oxidase activity) and shifted to a fungi-dominated community composition. These responses suggest that microbial C availability decreased and microbes allocated more energy to obtain C and nutrients from biochemically resistant substrates under eO₃. Elevated O₃ decreased bacterial necromass C and total necromass C, which could explain the observed decreases in mineral-associated organic C and SOC. The effects of eO₃ on soil microbial C availability and community composition were strengthened by N addition, whereas there were no differences in the below-ground effects of eO₃ between the two poplar clones. Taken together, the increased soil extracellular enzyme activities and slightly increased particulate organic C content suggest that the microbial C pump pathway via microbial ex vivo modification was strengthened by eO₃, whereas the pathway via microbial in vivo turnover was weakened, as suggested by the decreases in soil microbial respiration, biomass, necromass, and mineral-associated organic C. Our study provides evidence that aboveground eO₃ effects on trees may affect belowground microbial processing of organic matter and ultimately the persistence of SOC.
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Please use this url to cite or link to this publication: https://lup.lub.lu.se/record/8c7c0fe0-9d91-435e-91a3-0b0a9797decd

author

Zheng, Haifeng ^LU ; Vesterdal, Lars ; Agathokleous, Evgenios ; Yuan, Xiangyang ; Yuan, Mingyue ^LU ; Xu, Yansen ; Heděnec, Petr ; Shang, Bo ; Feng, Zhaozhong and Rousk, Johannes ^LU

organization

publishing date

2024-11

type

Contribution to journal

publication status

published

subject

Soil Science

keywords

Amino sugar, Climate change, Microbial carbon availability, Microbial carbon pump, Soil carbon fractionation

in

Soil Biology and Biochemistry

volume

198

article number

109559

publisher

Elsevier

external identifiers

scopus:85201757324

ISSN

0038-0717

DOI

10.1016/j.soilbio.2024.109559

language

English

LU publication?

yes

id

8c7c0fe0-9d91-435e-91a3-0b0a9797decd

date added to LUP

2024-10-30 11:06:49

date last changed

2025-04-17 02:27:59

@article{8c7c0fe0-9d91-435e-91a3-0b0a9797decd,
  abstract     = {{<p>Elevated ozone (eO<sub>3</sub>) and atmospheric nitrogen (N) deposition are important climate change components that can affect plant growth and plant-soil-microbe interactions. However, the understanding of how eO<sub>3</sub> and its interaction with N deposition affect soil microbially mediated carbon (C) cycling and the fate of soil C stocks is limited. This study aimed to test how eO<sub>3</sub> and N deposition affected soil microbial metrics (i.e., respiration, enzyme activities, biomass, necromass, and community composition) and resulting soil organic C (SOC) fractions in the rhizosphere of poplar plantations with different sensitivity to O<sub>3</sub>. Exposure to O<sub>3</sub> and/or N deposition for four years was conducted within a free-air O<sub>3</sub> concentration-enrichment facility. Elevated O<sub>3</sub> reduced soil microbial respiration and biomass C but enhanced the enzymatic acquisition of C (i.e., potential soil hydrolase and oxidase activity) and shifted to a fungi-dominated community composition. These responses suggest that microbial C availability decreased and microbes allocated more energy to obtain C and nutrients from biochemically resistant substrates under eO<sub>3</sub>. Elevated O<sub>3</sub> decreased bacterial necromass C and total necromass C, which could explain the observed decreases in mineral-associated organic C and SOC. The effects of eO<sub>3</sub> on soil microbial C availability and community composition were strengthened by N addition, whereas there were no differences in the below-ground effects of eO<sub>3</sub> between the two poplar clones. Taken together, the increased soil extracellular enzyme activities and slightly increased particulate organic C content suggest that the microbial C pump pathway via microbial ex vivo modification was strengthened by eO<sub>3</sub>, whereas the pathway via microbial in vivo turnover was weakened, as suggested by the decreases in soil microbial respiration, biomass, necromass, and mineral-associated organic C. Our study provides evidence that aboveground eO<sub>3</sub> effects on trees may affect belowground microbial processing of organic matter and ultimately the persistence of SOC.</p>}},
  author       = {{Zheng, Haifeng and Vesterdal, Lars and Agathokleous, Evgenios and Yuan, Xiangyang and Yuan, Mingyue and Xu, Yansen and Heděnec, Petr and Shang, Bo and Feng, Zhaozhong and Rousk, Johannes}},
  issn         = {{0038-0717}},
  keywords     = {{Amino sugar; Climate change; Microbial carbon availability; Microbial carbon pump; Soil carbon fractionation}},
  language     = {{eng}},
  publisher    = {{Elsevier}},
  series       = {{Soil Biology and Biochemistry}},
  title        = {{Ozone strengthens the ex vivo but weakens the in vivo pathway of the microbial carbon pump in poplar plantations}},
  url          = {{http://dx.doi.org/10.1016/j.soilbio.2024.109559}},
  doi          = {{10.1016/j.soilbio.2024.109559}},
  volume       = {{198}},
  year         = {{2024}},
}

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Ozone strengthens the ex vivo but weakens the in vivo pathway of the microbial carbon pump in poplar plantations