Deciphering the associations between soil microbial diversity and ecosystem multifunctionality driven by long-term fertilization management

An increasing number of studies indicate that microbial diversity plays a crucial role in the mediation of ecosystem multifunctionality (EMF) in natural ecosystems. However, this point remains mostly overlooked in managed ecosystems, especially in agriculture. Here, we compiled promising strategies...

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Published inFunctional ecology Vol. 32; no. 4; pp. 1103 - 1116
Main Authors Luo, Gongwen, Rensing, Christopher, Chen, Huan, Liu, Manqiang, Wang, Min, Guo, Shiwei, Ling, Ning, Shen, Qirong
Format Journal Article
LanguageEnglish
Published London Wiley 01.04.2018
Wiley Subscription Services, Inc
Subjects
Agricultural ecosystems
Agricultural land
Agricultural management
agricultural soils
agroecosystems
Arable land
arable soils
China
climate
Communities
Data processing
Ecosystem management
ecosystem multifunctionality
ECOSYSTEMS ECOLOGY
Electromagnetic fields
Environmental changes
Enzymatic activity
enzymatic patterns
Enzyme activity
Enzymes
Exploitation
Fertilization
long‐term fertilization management
Low frequency
Mathematical models
Microbial activity
microbial diversity
Microorganisms
monsoon season
Physiochemistry
Redundancy
scanning electron microscopy
soil aggregation
Soil management
soil microorganisms
Soil properties
Structural equation modeling
structural equation modelling
China
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Abstract An increasing number of studies indicate that microbial diversity plays a crucial role in the mediation of ecosystem multifunctionality (EMF) in natural ecosystems. However, this point remains mostly overlooked in managed ecosystems, especially in agriculture. Here, we compiled promising strategies for the targeted exploitation of the associations between microbial diversity and EMF of agricultural soils using samples from two long‐term (more than 30 years) experimental field sites in southern China. The two sites experienced a similar monsoon climate and fertilization management practices. We used high‐throughput amplicon sequencing, structural equation modelling and random forest analysis, to analyse our data and validate our hypotheses. We found that soil physiochemical properties and the C‐, N‐, P‐ and S‐cycle enzyme activities were increased with the increase in microbial diversity. Specifically, a positive linear relationship was observed between microbial diversity and EMF, which was mediated by long‐term fertilization management via changes in soil microbial communities and physiochemical properties. Random forest analysis and SEM showed that the important role of microbial diversity on EMF was maintained even when simultaneously taking multiple multifunctionality drivers (soil physiochemical properties, soil aggregation and enzymatic patterns) into account. In addition, microbial diversity, C‐cycle enzyme activity and pH value are feasible predictors of EMF; these factors were shown to be the main drivers of EMF of arable soils. Our findings suggest that there may be a limited degree of multifunctional redundancy in arable soils. The relationship we observed between microbial diversity and EMF suggests that management practices that foster more diverse soil microbial communities may have the potential to improve the functioning of agroecosystems. A plain language summary is available for this article. Plain Language Summary
AbstractList An increasing number of studies indicate that microbial diversity plays a crucial role in the mediation of ecosystem multifunctionality ( EMF ) in natural ecosystems. However, this point remains mostly overlooked in managed ecosystems, especially in agriculture. Here, we compiled promising strategies for the targeted exploitation of the associations between microbial diversity and EMF of agricultural soils using samples from two long‐term (more than 30 years) experimental field sites in southern China. The two sites experienced a similar monsoon climate and fertilization management practices. We used high‐throughput amplicon sequencing, structural equation modelling and random forest analysis, to analyse our data and validate our hypotheses. We found that soil physiochemical properties and the C‐, N‐, P‐ and S‐cycle enzyme activities were increased with the increase in microbial diversity. Specifically, a positive linear relationship was observed between microbial diversity and EMF , which was mediated by long‐term fertilization management via changes in soil microbial communities and physiochemical properties. Random forest analysis and SEM showed that the important role of microbial diversity on EMF was maintained even when simultaneously taking multiple multifunctionality drivers (soil physiochemical properties, soil aggregation and enzymatic patterns) into account. In addition, microbial diversity, C‐cycle enzyme activity and pH value are feasible predictors of EMF ; these factors were shown to be the main drivers of EMF of arable soils. Our findings suggest that there may be a limited degree of multifunctional redundancy in arable soils. The relationship we observed between microbial diversity and EMF suggests that management practices that foster more diverse soil microbial communities may have the potential to improve the functioning of agroecosystems. A plain language summary is available for this article.
An increasing number of studies indicate that microbial diversity plays a crucial role in the mediation of ecosystem multifunctionality (EMF) in natural ecosystems. However, this point remains mostly overlooked in managed ecosystems, especially in agriculture. Here, we compiled promising strategies for the targeted exploitation of the associations between microbial diversity and EMF of agricultural soils using samples from two long‐term (more than 30 years) experimental field sites in southern China. The two sites experienced a similar monsoon climate and fertilization management practices. We used high‐throughput amplicon sequencing, structural equation modelling and random forest analysis, to analyse our data and validate our hypotheses. We found that soil physiochemical properties and the C‐, N‐, P‐ and S‐cycle enzyme activities were increased with the increase in microbial diversity. Specifically, a positive linear relationship was observed between microbial diversity and EMF, which was mediated by long‐term fertilization management via changes in soil microbial communities and physiochemical properties. Random forest analysis and SEM showed that the important role of microbial diversity on EMF was maintained even when simultaneously taking multiple multifunctionality drivers (soil physiochemical properties, soil aggregation and enzymatic patterns) into account. In addition, microbial diversity, C‐cycle enzyme activity and pH value are feasible predictors of EMF; these factors were shown to be the main drivers of EMF of arable soils. Our findings suggest that there may be a limited degree of multifunctional redundancy in arable soils. The relationship we observed between microbial diversity and EMF suggests that management practices that foster more diverse soil microbial communities may have the potential to improve the functioning of agroecosystems. A plain language summary is available for this article.
An increasing number of studies indicate that microbial diversity plays a crucial role in the mediation of ecosystem multifunctionality (EMF) in natural ecosystems. However, this point remains mostly overlooked in managed ecosystems, especially in agriculture. Here, we compiled promising strategies for the targeted exploitation of the associations between microbial diversity and EMF of agricultural soils using samples from two long‐term (more than 30 years) experimental field sites in southern China. The two sites experienced a similar monsoon climate and fertilization management practices. We used high‐throughput amplicon sequencing, structural equation modelling and random forest analysis, to analyse our data and validate our hypotheses. We found that soil physiochemical properties and the C‐, N‐, P‐ and S‐cycle enzyme activities were increased with the increase in microbial diversity. Specifically, a positive linear relationship was observed between microbial diversity and EMF, which was mediated by long‐term fertilization management via changes in soil microbial communities and physiochemical properties. Random forest analysis and SEM showed that the important role of microbial diversity on EMF was maintained even when simultaneously taking multiple multifunctionality drivers (soil physiochemical properties, soil aggregation and enzymatic patterns) into account. In addition, microbial diversity, C‐cycle enzyme activity and pH value are feasible predictors of EMF; these factors were shown to be the main drivers of EMF of arable soils. Our findings suggest that there may be a limited degree of multifunctional redundancy in arable soils. The relationship we observed between microbial diversity and EMF suggests that management practices that foster more diverse soil microbial communities may have the potential to improve the functioning of agroecosystems. A plain language summary is available for this article. Plain Language Summary
Author Ling, Ning
Luo, Gongwen
Shen, Qirong
Chen, Huan
Rensing, Christopher
Wang, Min
Guo, Shiwei
Liu, Manqiang
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  givenname: Gongwen
  surname: Luo
  fullname: Luo, Gongwen
– sequence: 2
  givenname: Christopher
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– sequence: 3
  givenname: Huan
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– sequence: 4
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  givenname: Shiwei
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– sequence: 7
  givenname: Ning
  surname: Ling
  fullname: Ling, Ning
– sequence: 8
  givenname: Qirong
  surname: Shen
  fullname: Shen, Qirong
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Snippet An increasing number of studies indicate that microbial diversity plays a crucial role in the mediation of ecosystem multifunctionality (EMF) in natural...
An increasing number of studies indicate that microbial diversity plays a crucial role in the mediation of ecosystem multifunctionality ( EMF ) in natural...
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SubjectTerms Agricultural ecosystems
Agricultural land
Agricultural management
agricultural soils
agroecosystems
Arable land
arable soils
China
climate
Communities
Data processing
Ecosystem management
ecosystem multifunctionality
ECOSYSTEMS ECOLOGY
Electromagnetic fields
Environmental changes
Enzymatic activity
enzymatic patterns
Enzyme activity
Enzymes
Exploitation
Fertilization
long‐term fertilization management
Low frequency
Mathematical models
Microbial activity
microbial diversity
Microorganisms
monsoon season
Physiochemistry
Redundancy
scanning electron microscopy
soil aggregation
Soil management
soil microorganisms
Soil properties
Structural equation modeling
structural equation modelling
Title Deciphering the associations between soil microbial diversity and ecosystem multifunctionality driven by long-term fertilization management
URI https://www.jstor.org/stable/48582674
https://onlinelibrary.wiley.com/doi/abs/10.1111%2F1365-2435.13039
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Volume 32
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