Plants increase laccase activity in soil with long-term elevated CO2 legacy

Asrin  Partavian; Teis N. Mikkelsen; Mette Vestergård

doi:10.1016/j.ejsobi.2015.08.002

Plants increase laccase activity in soil with long-term elevated CO₂ legacy

Asrin Partavian, Teis N. Mikkelsen, Mette Vestergård

Terrestrial Ecology

5 Citations (Scopus)

Abstract

Actively growing plants can stimulate mineralization of recalcitrant soil organic matter (SOM), and increased atmospheric [CO₂] can further enhance such plant-mediated SOM degradation. Laccases are central for recalcitrant SOM decomposition, and we therefore hypothesized that plants and elevated [CO₂] stimulate laccase activity. We incubated soil exposed to seven years of elevated or ambient field [CO₂] in ambient or elevated [CO₂] chambers for six months either with or without plants (Deschampsia flexuosa). Elevated chamber [CO₂] increased D. flexuosa production and belowground respiration. Interestingly, plants also grew larger in soil with an elevated [CO₂] legacy. Plants stimulated soil microbial biomass, belowground respiration and laccase activity, and the plant-induced laccase stimulation was particularly apparent in soil exposed to long-term elevated [CO₂] in the field, whereas laccase activity was unaffected by short-term chamber [CO₂]. Hence, actively growing plants can stimulate laccase activity, but the potential for plant-induced laccase production appears to depend on the laccase production potential of the soil. Further, initial differences in laccase production potential prevailed during the six months experimental period independent of current [CO₂], although plant production increased at elevated [CO₂] during this period. Taken together, these findings suggest that although laccase activity depends on plant presence, the laccase production potential does not respond fast to increased plant production.

Original language	English
Journal	European Journal of Soil Biology
Volume	70
Pages (from-to)	97-103
Number of pages	7
ISSN	1164-5563
DOIs	https://doi.org/10.1016/j.ejsobi.2015.08.002
Publication status	Published - 1 Sept 2015

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10.1016/j.ejsobi.2015.08.002

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@article{21a9ba41f85a4b32bd72e91935093532,

title = "Plants increase laccase activity in soil with long-term elevated CO2 legacy",

abstract = "Actively growing plants can stimulate mineralization of recalcitrant soil organic matter (SOM), and increased atmospheric [CO2] can further enhance such plant-mediated SOM degradation. Laccases are central for recalcitrant SOM decomposition, and we therefore hypothesized that plants and elevated [CO2] stimulate laccase activity. We incubated soil exposed to seven years of elevated or ambient field [CO2] in ambient or elevated [CO2] chambers for six months either with or without plants (Deschampsia flexuosa). Elevated chamber [CO2] increased D. flexuosa production and belowground respiration. Interestingly, plants also grew larger in soil with an elevated [CO2] legacy. Plants stimulated soil microbial biomass, belowground respiration and laccase activity, and the plant-induced laccase stimulation was particularly apparent in soil exposed to long-term elevated [CO2] in the field, whereas laccase activity was unaffected by short-term chamber [CO2]. Hence, actively growing plants can stimulate laccase activity, but the potential for plant-induced laccase production appears to depend on the laccase production potential of the soil. Further, initial differences in laccase production potential prevailed during the six months experimental period independent of current [CO2], although plant production increased at elevated [CO2] during this period. Taken together, these findings suggest that although laccase activity depends on plant presence, the laccase production potential does not respond fast to increased plant production.",

author = "Asrin Partavian and Mikkelsen, {Teis N.} and Mette Vesterg{\aa}rd",

year = "2015",

month = sep,

day = "1",

doi = "10.1016/j.ejsobi.2015.08.002",

language = "English",

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pages = "97--103",

journal = "European Journal of Soil Biology",

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TY - JOUR

T1 - Plants increase laccase activity in soil with long-term elevated CO2 legacy

AU - Partavian, Asrin

AU - Mikkelsen, Teis N.

AU - Vestergård, Mette

PY - 2015/9/1

Y1 - 2015/9/1

N2 - Actively growing plants can stimulate mineralization of recalcitrant soil organic matter (SOM), and increased atmospheric [CO2] can further enhance such plant-mediated SOM degradation. Laccases are central for recalcitrant SOM decomposition, and we therefore hypothesized that plants and elevated [CO2] stimulate laccase activity. We incubated soil exposed to seven years of elevated or ambient field [CO2] in ambient or elevated [CO2] chambers for six months either with or without plants (Deschampsia flexuosa). Elevated chamber [CO2] increased D. flexuosa production and belowground respiration. Interestingly, plants also grew larger in soil with an elevated [CO2] legacy. Plants stimulated soil microbial biomass, belowground respiration and laccase activity, and the plant-induced laccase stimulation was particularly apparent in soil exposed to long-term elevated [CO2] in the field, whereas laccase activity was unaffected by short-term chamber [CO2]. Hence, actively growing plants can stimulate laccase activity, but the potential for plant-induced laccase production appears to depend on the laccase production potential of the soil. Further, initial differences in laccase production potential prevailed during the six months experimental period independent of current [CO2], although plant production increased at elevated [CO2] during this period. Taken together, these findings suggest that although laccase activity depends on plant presence, the laccase production potential does not respond fast to increased plant production.

AB - Actively growing plants can stimulate mineralization of recalcitrant soil organic matter (SOM), and increased atmospheric [CO2] can further enhance such plant-mediated SOM degradation. Laccases are central for recalcitrant SOM decomposition, and we therefore hypothesized that plants and elevated [CO2] stimulate laccase activity. We incubated soil exposed to seven years of elevated or ambient field [CO2] in ambient or elevated [CO2] chambers for six months either with or without plants (Deschampsia flexuosa). Elevated chamber [CO2] increased D. flexuosa production and belowground respiration. Interestingly, plants also grew larger in soil with an elevated [CO2] legacy. Plants stimulated soil microbial biomass, belowground respiration and laccase activity, and the plant-induced laccase stimulation was particularly apparent in soil exposed to long-term elevated [CO2] in the field, whereas laccase activity was unaffected by short-term chamber [CO2]. Hence, actively growing plants can stimulate laccase activity, but the potential for plant-induced laccase production appears to depend on the laccase production potential of the soil. Further, initial differences in laccase production potential prevailed during the six months experimental period independent of current [CO2], although plant production increased at elevated [CO2] during this period. Taken together, these findings suggest that although laccase activity depends on plant presence, the laccase production potential does not respond fast to increased plant production.

U2 - 10.1016/j.ejsobi.2015.08.002

DO - 10.1016/j.ejsobi.2015.08.002

M3 - Journal article

SN - 1164-5563

VL - 70

SP - 97

EP - 103

JO - European Journal of Soil Biology

JF - European Journal of Soil Biology

ER -

Plants increase laccase activity in soil with long-term elevated CO2 legacy

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Plants increase laccase activity in soil with long-term elevated CO₂ legacy