首页|Trade-off between microbial carbon use efficiency and specific nutrient-acquiring extracellular enzyme activities under reduced oxygen

Trade-off between microbial carbon use efficiency and specific nutrient-acquiring extracellular enzyme activities under reduced oxygen

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Reduced oxygen increased microbial metabolic quotient(qCO2).Reduced oxygen enhanced microbial specific C-,N-and P-acquiring enzyme activity.Reduced oxygen increased microbial C relative to N and P limitation.Reduced oxygen increased microbial N relative to P limitation.Specific enzyme activity was positively related to qCO2 under reduced oxygen.Mangroves are one of the most ecologically sensitive ecosystems to global climate change,which have cascading impacts on soil carbon(C),nitrogen(N)and phosphorus(P)cycling.Moreover,mangroves are experiencing increasing N and P loadings and reduced oxygen availability due to intensified climate change and human activities.However,both direct and interactive effects of these perturbations on microbially mediated soil C,N and P cycling are poorly understood.Here,we simultaneously investigated the effects of N and P loadings and reduced oxygen on microbial biomass,microbial respiration,and extracellular enzyme activities(EEAs)in mangrove soils.We calculated the microbial metabolic quotient(qCO2),which is regarded as a useful inverse metric of microbial C use efficiency(CUE).Our results show that reduced oxygen significantly increases both qCO2 and microbial specific EEAs(enzyme activity per unit of microbial biomass)for C-,N-and P-acquisition regardless of N or P loadings.Furthermore,we found that qCO2 positively correlated with microbial specific EEAs under reduced oxygen,whereas no clear relationship was detected under ambient oxygen.These results suggest that reduced oxygen increases microbial specific EEAs at the expense of increasing microbial respiration per unit biomass,indicating higher energy cost per unit enzyme production.

reduced oxygenextracellular enzymemicrobial respirationnutrient acquisitionnutrient additionmangrove

Ji Chen、Irene Cordero、Daryl L.Moorhead、Jennifer K.Rowntree、Loraé T.Simpson、Richard D.Bardgett、Hayley Craig

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Department of Agroecology,Aarhus University,8830 Tjele,Denmark

Aarhus University Centre for Circular Bioeconomy,Aarhus University,8830 Tjele,Denmark

iCLIMATE Interdisciplinary Centre for Climate Change,Aarhus University,4000 Roskilde,Denmark

Department of Earth and Environmental Sciences,The University of Manchester,Oxford Road,Manchester,M13 9PT,UK

Department of Environmental Sciences,University of Toledo,2801 W.Bancroft St.,Toledo,OH 43606-3390,USA

School of Biological and Marine Sciences,University of Plymouth,Drake Circus,Plymouth,PL4 8AA,UK

Florida Oceanographic Society,890 NE Ocean Blvd,Stuart,FL 34996,USA

NatureMetrics,Occam Court,Surrey Research Park,Guildford,GU2 7HJ,UK

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EU H2020 Marie Sklodowska-Curie ActionsAarhus Universitets ForskningsfondDanish Independent Research FoundationNordic Committee of Agriculture and Food ResearchNatural Environment Research Council(NERC)EAO Doctoral Training Partnershipa Ramon Areces Foundation research Fellowship and BBSRC Discovery Fellowship

839806AUFF-E-2019-7-11127-00015BNE/L002469/1BB/S010661/1

2023

土壤生态学快报(英文)

土壤生态学快报(英文)

CSCD
ISSN:
年,卷(期):2023.5(2)
  • 69