Spatial turnover of multiple ecosystem functions is more associated with plant than soil microbial β-diversity

Lancaster Environment Centre

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https://doi.org/10.1002/ecs2.3644
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Available under license: CC BY: Creative Commons Attribution 4.0 International License

Keywords

aboveground–belowground linkages, ecosystem functions, grasslands, multifunctionality, Nutrient Network, soil fungi and bacteria, β-diversity

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Research output: Contribution to Journal/Magazine › Journal article › peer-review

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Spatial turnover of multiple ecosystem functions is more associated with plant than soil microbial β-diversity. / Jing, X.; Prager, C.M.; Borer, E.T. et al.
In: Ecosphere, Vol. 12, No. 7, e03644, 31.07.2021.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Harvard

Jing, X, Prager, CM, Borer, ET, Gotelli, NJ, Gruner, DS, He, J-S, Kirkman, K, MacDougall, AS, McCulley, RL, Prober, SM, Seabloom, EW, Stevens, CJ, Classen, AT & Sanders, NJ 2021, 'Spatial turnover of multiple ecosystem functions is more associated with plant than soil microbial β-diversity', Ecosphere, vol. 12, no. 7, e03644. https://doi.org/10.1002/ecs2.3644

APA

Jing, X., Prager, C. M., Borer, E. T., Gotelli, N. J., Gruner, D. S., He, J.-S., Kirkman, K., MacDougall, A. S., McCulley, R. L., Prober, S. M., Seabloom, E. W., Stevens, C. J., Classen, A. T., & Sanders, N. J. (2021). Spatial turnover of multiple ecosystem functions is more associated with plant than soil microbial β-diversity. Ecosphere, 12(7), Article e03644. https://doi.org/10.1002/ecs2.3644

Vancouver

Jing X, Prager CM, Borer ET, Gotelli NJ, Gruner DS, He JS et al. Spatial turnover of multiple ecosystem functions is more associated with plant than soil microbial β-diversity. Ecosphere. 2021 Jul 31;12(7):e03644. Epub 2021 Jul 21. doi: 10.1002/ecs2.3644

Author

Jing, X. ; Prager, C.M. ; Borer, E.T. et al. / Spatial turnover of multiple ecosystem functions is more associated with plant than soil microbial β-diversity. In: Ecosphere. 2021 ; Vol. 12, No. 7.

Bibtex

@article{249898ff59c5486184b60a9b8ffa33ae,

title = "Spatial turnover of multiple ecosystem functions is more associated with plant than soil microbial β-diversity",

abstract = "Biodiversity—both above- and belowground—influences multiple functions in terrestrial ecosystems. Yet, it is unclear whether differences in above- and belowground species composition (β-diversity) are associated with differences in multiple ecosystem functions (e.g., spatial turnover in ecosystem function). Here, we partitioned the contributions of above- and belowground β-diversity and abiotic factors (geographic distance, differences in environments) on the spatial turnover of multiple grassland ecosystem functions. We compiled a dataset of plant and soil microbial communities and six indicators of grassland ecosystem functions (i.e., plant aboveground live biomass, plant nitrogen [N], plant phosphorus [P], root biomass, soil total N, and soil extractable P) from 18 grassland sites on four continents contributing to the Nutrient Network experiment. We used Mantel tests and structural equation models to disentangle the relationship between above- and belowground β-diversity and spatial turnover in grassland ecosystem functions. We found that the effects of abiotic factors on the spatial turnover of ecosystem functions were largely indirect through their influences on above- and belowground β-diversity, and that spatial turnover of ecosystem function was more strongly associated with plant β-diversity than with soil microbial β-diversity. These results indicate that changes in above- and belowground species composition are one mechanism that interacts with environmental change to determine variability in multiple ecosystem functions across spatial scales. As grasslands face global threats from shrub encroachment, conversion to agriculture, or are lost to development, the functions and services they provide will more strongly converge with increased aboveground community homogenization than with soil microbial community homogenization. ",

keywords = "aboveground–belowground linkages, ecosystem functions, grasslands, multifunctionality, Nutrient Network, soil fungi and bacteria, β-diversity",

author = "X. Jing and C.M. Prager and E.T. Borer and N.J. Gotelli and D.S. Gruner and J.-S. He and K. Kirkman and A.S. MacDougall and R.L. McCulley and S.M. Prober and E.W. Seabloom and C.J. Stevens and A.T. Classen and N.J. Sanders",

year = "2021",

month = jul,

day = "31",

doi = "10.1002/ecs2.3644",

language = "English",

volume = "12",

journal = "Ecosphere",

issn = "2150-8925",

publisher = "ECOLOGICAL SOC AMER",

number = "7",

}

RIS

TY - JOUR

T1 - Spatial turnover of multiple ecosystem functions is more associated with plant than soil microbial β-diversity

AU - Jing, X.

AU - Prager, C.M.

AU - Borer, E.T.

AU - Gotelli, N.J.

AU - Gruner, D.S.

AU - He, J.-S.

AU - Kirkman, K.

AU - MacDougall, A.S.

AU - McCulley, R.L.

AU - Prober, S.M.

AU - Seabloom, E.W.

AU - Stevens, C.J.

AU - Classen, A.T.

AU - Sanders, N.J.

PY - 2021/7/31

Y1 - 2021/7/31

N2 - Biodiversity—both above- and belowground—influences multiple functions in terrestrial ecosystems. Yet, it is unclear whether differences in above- and belowground species composition (β-diversity) are associated with differences in multiple ecosystem functions (e.g., spatial turnover in ecosystem function). Here, we partitioned the contributions of above- and belowground β-diversity and abiotic factors (geographic distance, differences in environments) on the spatial turnover of multiple grassland ecosystem functions. We compiled a dataset of plant and soil microbial communities and six indicators of grassland ecosystem functions (i.e., plant aboveground live biomass, plant nitrogen [N], plant phosphorus [P], root biomass, soil total N, and soil extractable P) from 18 grassland sites on four continents contributing to the Nutrient Network experiment. We used Mantel tests and structural equation models to disentangle the relationship between above- and belowground β-diversity and spatial turnover in grassland ecosystem functions. We found that the effects of abiotic factors on the spatial turnover of ecosystem functions were largely indirect through their influences on above- and belowground β-diversity, and that spatial turnover of ecosystem function was more strongly associated with plant β-diversity than with soil microbial β-diversity. These results indicate that changes in above- and belowground species composition are one mechanism that interacts with environmental change to determine variability in multiple ecosystem functions across spatial scales. As grasslands face global threats from shrub encroachment, conversion to agriculture, or are lost to development, the functions and services they provide will more strongly converge with increased aboveground community homogenization than with soil microbial community homogenization.

AB - Biodiversity—both above- and belowground—influences multiple functions in terrestrial ecosystems. Yet, it is unclear whether differences in above- and belowground species composition (β-diversity) are associated with differences in multiple ecosystem functions (e.g., spatial turnover in ecosystem function). Here, we partitioned the contributions of above- and belowground β-diversity and abiotic factors (geographic distance, differences in environments) on the spatial turnover of multiple grassland ecosystem functions. We compiled a dataset of plant and soil microbial communities and six indicators of grassland ecosystem functions (i.e., plant aboveground live biomass, plant nitrogen [N], plant phosphorus [P], root biomass, soil total N, and soil extractable P) from 18 grassland sites on four continents contributing to the Nutrient Network experiment. We used Mantel tests and structural equation models to disentangle the relationship between above- and belowground β-diversity and spatial turnover in grassland ecosystem functions. We found that the effects of abiotic factors on the spatial turnover of ecosystem functions were largely indirect through their influences on above- and belowground β-diversity, and that spatial turnover of ecosystem function was more strongly associated with plant β-diversity than with soil microbial β-diversity. These results indicate that changes in above- and belowground species composition are one mechanism that interacts with environmental change to determine variability in multiple ecosystem functions across spatial scales. As grasslands face global threats from shrub encroachment, conversion to agriculture, or are lost to development, the functions and services they provide will more strongly converge with increased aboveground community homogenization than with soil microbial community homogenization.

KW - aboveground–belowground linkages

KW - ecosystem functions

KW - grasslands

KW - multifunctionality

KW - Nutrient Network

KW - soil fungi and bacteria

KW - β-diversity

U2 - 10.1002/ecs2.3644

DO - 10.1002/ecs2.3644

M3 - Journal article

VL - 12

JO - Ecosphere

JF - Ecosphere

SN - 2150-8925

IS - 7

M1 - e03644

ER -

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