Global decomposition experiment shows soil animal impacts on decomposition are climate-dependent

Diana H. Wall; Mark A. Bradford; Mark G. St. John; John A. Trofymow; Valerie Behan-Pelletier; David E. Bignell; J. Mark Dangerfield; William J. Parton; Josef Rusek; Winfried Voigt; Volkmar Wolters; Holley Zadeh Gardel; Fredo O. Ayuke; Richard Bashford; Olga I. Beljakova; Patrick J. Bohlen; Alain Brauman; Stephen Flemming; Joh R. Henschel; Dan L. Johnson; T. Helfin Jones; Marcela Kovarova; J. Marty Kranabetter; Les Kutny; Kuo Chuan Lin; Mohamed Maryati; Dominique Masse; Andrei Pokarzhevskii; Homathevi Rahman; Millor G. Sabará; Joerg Alfred Salamon; Michael J. Swift; Amanda Varela; Heraldo L. Vasconcelos; Don White; Xiaoming Zou

doi:10.1111/j.1365-2486.2008.01672.x

Global decomposition experiment shows soil animal impacts on decomposition are climate-dependent

Diana H. Wall
, Mark A. Bradford
, Mark G. St. John
, John A. Trofymow
, Valerie Behan-Pelletier
, David E. Bignell
, J. Mark Dangerfield
, William J. Parton
, Josef Rusek
, Winfried Voigt
, Volkmar Wolters
, Holley Zadeh Gardel
, Fredo O. Ayuke
, Richard Bashford
, Olga I. Beljakova
, Patrick J. Bohlen
, Alain Brauman
, Stephen Flemming
, Joh R. Henschel
, Dan L. Johnson

T. Helfin Jones, Marcela Kovarova, J. Marty Kranabetter, Les Kutny, Kuo Chuan Lin, Mohamed Maryati, Dominique Masse, Andrei Pokarzhevskii, Homathevi Rahman, Millor G. Sabará, Joerg Alfred Salamon, Michael J. Swift, Amanda Varela, Heraldo L. Vasconcelos, Don White, Xiaoming Zou

Colorado State University
University of Georgia
Landcare Research
Canadian Forest Service
Agriculture and Agri-Food Canada
Queen Mary University of London
Macquarie University
Institute of Soil Biology Ceske Budejovice
Friedrich Schiller University Jena
Justus Liebig University Giessen
Kenya Methodist University
Forestry Tasmania
Centralno-Chernozemnyj Reserve
MacArthur Agro-Ecology Research Center
UR SeqBio
Gobabeb Namib Research Institute
University of Lethbridge
Cardiff University
Institute of Botany of the Academy of Sciences of the Czech Republic
Government of British Columbia
Inuvik Research Centre
Taiwan Forestry Research Institute
Universiti Malaysia Sabah
Institut de recherche pour le développement
Russian Academy of Sciences
Centro Universitário do Leste de Minas Gerais
World Agroforestry Centre
Universidade Federal de Uberlândia
Department of Indian and Northern Affairs
Xishuangbanna Tropical Botanical Garden Chinese Academy of Sciences Kunming
University of Puerto Rico

Research output: Contribution to journal › Article › peer-review

431 Scopus citations

Abstract

Climate and litter quality are primary drivers of terrestrial decomposition and, based on evidence from multisite experiments at regional and global scales, are universally factored into global decomposition models. In contrast, soil animals are considered key regulators of decomposition at local scales but their role at larger scales is unresolved. Soil animals are consequently excluded from global models of organic mineralization processes. Incomplete assessment of the roles of soil animals stems from the difficulties of manipulating invertebrate animals experimentally across large geographic gradients. This is compounded by deficient or inconsistent taxonomy. We report a global decomposition experiment to assess the importance of soil animals in C mineralization, in which a common grass litter substrate was exposed to natural decomposition in either control or reduced animal treatments across 30 sites distributed from 43°S to 68°N on six continents. Animals in the mesofaunal size range were recovered from the litter by Tullgren extraction and identified to common specifications, mostly at the ordinal level. The design of the trials enabled faunal contribution to be evaluated against abiotic parameters between sites. Soil animals increase decomposition rates in temperate and wet tropical climates, but have neutral effects where temperature or moisture constrain biological activity. Our findings highlight that faunal influences on decomposition are dependent on prevailing climatic conditions. We conclude that (1) inclusion of soil animals will improve the predictive capabilities of region- or biome-scale decomposition models, (2) soil animal influences on decomposition are important at the regional scale when attempting to predict global change scenarios, and (3) the statistical relationship between decomposition rates and climate, at the global scale, is robust against changes in soil faunal abundance and diversity.

Original language	English
Pages (from-to)	2661-2677
Number of pages	17
Journal	Global Change Biology
Volume	14
Issue number	11
DOIs	https://doi.org/10.1111/j.1365-2486.2008.01672.x
State	Published - 2008

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 13 Climate Action

Keywords

Climate decomposition index
Decomposition
Litter
Mesofauna
Soil biodiversity
Soil carbon
Soil fauna

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10.1111/j.1365-2486.2008.01672.x

Cite this

Wall, D. H., Bradford, M. A., St. John, M. G., Trofymow, J. A., Behan-Pelletier, V., Bignell, D. E., Dangerfield, J. M., Parton, W. J., Rusek, J., Voigt, W., Wolters, V., Gardel, H. Z., Ayuke, F. O., Bashford, R., Beljakova, O. I., Bohlen, P. J., Brauman, A., Flemming, S., Henschel, J. R., ... Zou, X. (2008). Global decomposition experiment shows soil animal impacts on decomposition are climate-dependent. Global Change Biology, 14(11), 2661-2677. https://doi.org/10.1111/j.1365-2486.2008.01672.x

@article{3820b2da7d3642579c1a422c95a04c33,

title = "Global decomposition experiment shows soil animal impacts on decomposition are climate-dependent",

abstract = "Climate and litter quality are primary drivers of terrestrial decomposition and, based on evidence from multisite experiments at regional and global scales, are universally factored into global decomposition models. In contrast, soil animals are considered key regulators of decomposition at local scales but their role at larger scales is unresolved. Soil animals are consequently excluded from global models of organic mineralization processes. Incomplete assessment of the roles of soil animals stems from the difficulties of manipulating invertebrate animals experimentally across large geographic gradients. This is compounded by deficient or inconsistent taxonomy. We report a global decomposition experiment to assess the importance of soil animals in C mineralization, in which a common grass litter substrate was exposed to natural decomposition in either control or reduced animal treatments across 30 sites distributed from 43°S to 68°N on six continents. Animals in the mesofaunal size range were recovered from the litter by Tullgren extraction and identified to common specifications, mostly at the ordinal level. The design of the trials enabled faunal contribution to be evaluated against abiotic parameters between sites. Soil animals increase decomposition rates in temperate and wet tropical climates, but have neutral effects where temperature or moisture constrain biological activity. Our findings highlight that faunal influences on decomposition are dependent on prevailing climatic conditions. We conclude that (1) inclusion of soil animals will improve the predictive capabilities of region- or biome-scale decomposition models, (2) soil animal influences on decomposition are important at the regional scale when attempting to predict global change scenarios, and (3) the statistical relationship between decomposition rates and climate, at the global scale, is robust against changes in soil faunal abundance and diversity.",

keywords = "Climate decomposition index, Decomposition, Litter, Mesofauna, Soil biodiversity, Soil carbon, Soil fauna",

author = "Wall, \{Diana H.\} and Bradford, \{Mark A.\} and \{St. John\}, \{Mark G.\} and Trofymow, \{John A.\} and Valerie Behan-Pelletier and Bignell, \{David E.\} and Dangerfield, \{J. Mark\} and Parton, \{William J.\} and Josef Rusek and Winfried Voigt and Volkmar Wolters and Gardel, \{Holley Zadeh\} and Ayuke, \{Fredo O.\} and Richard Bashford and Beljakova, \{Olga I.\} and Bohlen, \{Patrick J.\} and Alain Brauman and Stephen Flemming and Henschel, \{Joh R.\} and Johnson, \{Dan L.\} and Jones, \{T. Helfin\} and Marcela Kovarova and Kranabetter, \{J. Marty\} and Les Kutny and Lin, \{Kuo Chuan\} and Mohamed Maryati and Dominique Masse and Andrei Pokarzhevskii and Homathevi Rahman and Sabar{\'a}, \{Millor G.\} and Salamon, \{Joerg Alfred\} and Swift, \{Michael J.\} and Amanda Varela and Vasconcelos, \{Heraldo L.\} and Don White and Xiaoming Zou",

year = "2008",

doi = "10.1111/j.1365-2486.2008.01672.x",

language = "English",

volume = "14",

pages = "2661--2677",

journal = "Global Change Biology",

issn = "1354-1013",

publisher = "Wiley-Blackwell Publishing Ltd",

number = "11",

}

Wall, DH, Bradford, MA, St. John, MG, Trofymow, JA, Behan-Pelletier, V, Bignell, DE, Dangerfield, JM, Parton, WJ, Rusek, J, Voigt, W, Wolters, V, Gardel, HZ, Ayuke, FO, Bashford, R, Beljakova, OI, Bohlen, PJ, Brauman, A, Flemming, S, Henschel, JR, Johnson, DL, Jones, TH, Kovarova, M, Kranabetter, JM, Kutny, L, Lin, KC, Maryati, M, Masse, D, Pokarzhevskii, A, Rahman, H, Sabará, MG, Salamon, JA, Swift, MJ, Varela, A, Vasconcelos, HL, White, D & Zou, X 2008, 'Global decomposition experiment shows soil animal impacts on decomposition are climate-dependent', Global Change Biology, vol. 14, no. 11, pp. 2661-2677. https://doi.org/10.1111/j.1365-2486.2008.01672.x

TY - JOUR

T1 - Global decomposition experiment shows soil animal impacts on decomposition are climate-dependent

AU - Wall, Diana H.

AU - Bradford, Mark A.

AU - St. John, Mark G.

AU - Trofymow, John A.

AU - Behan-Pelletier, Valerie

AU - Bignell, David E.

AU - Dangerfield, J. Mark

AU - Parton, William J.

AU - Rusek, Josef

AU - Voigt, Winfried

AU - Wolters, Volkmar

AU - Gardel, Holley Zadeh

AU - Ayuke, Fredo O.

AU - Bashford, Richard

AU - Beljakova, Olga I.

AU - Bohlen, Patrick J.

AU - Brauman, Alain

AU - Flemming, Stephen

AU - Henschel, Joh R.

AU - Johnson, Dan L.

AU - Jones, T. Helfin

AU - Kovarova, Marcela

AU - Kranabetter, J. Marty

AU - Kutny, Les

AU - Lin, Kuo Chuan

AU - Maryati, Mohamed

AU - Masse, Dominique

AU - Pokarzhevskii, Andrei

AU - Rahman, Homathevi

AU - Sabará, Millor G.

AU - Salamon, Joerg Alfred

AU - Swift, Michael J.

AU - Varela, Amanda

AU - Vasconcelos, Heraldo L.

AU - White, Don

AU - Zou, Xiaoming

PY - 2008

Y1 - 2008

N2 - Climate and litter quality are primary drivers of terrestrial decomposition and, based on evidence from multisite experiments at regional and global scales, are universally factored into global decomposition models. In contrast, soil animals are considered key regulators of decomposition at local scales but their role at larger scales is unresolved. Soil animals are consequently excluded from global models of organic mineralization processes. Incomplete assessment of the roles of soil animals stems from the difficulties of manipulating invertebrate animals experimentally across large geographic gradients. This is compounded by deficient or inconsistent taxonomy. We report a global decomposition experiment to assess the importance of soil animals in C mineralization, in which a common grass litter substrate was exposed to natural decomposition in either control or reduced animal treatments across 30 sites distributed from 43°S to 68°N on six continents. Animals in the mesofaunal size range were recovered from the litter by Tullgren extraction and identified to common specifications, mostly at the ordinal level. The design of the trials enabled faunal contribution to be evaluated against abiotic parameters between sites. Soil animals increase decomposition rates in temperate and wet tropical climates, but have neutral effects where temperature or moisture constrain biological activity. Our findings highlight that faunal influences on decomposition are dependent on prevailing climatic conditions. We conclude that (1) inclusion of soil animals will improve the predictive capabilities of region- or biome-scale decomposition models, (2) soil animal influences on decomposition are important at the regional scale when attempting to predict global change scenarios, and (3) the statistical relationship between decomposition rates and climate, at the global scale, is robust against changes in soil faunal abundance and diversity.

AB - Climate and litter quality are primary drivers of terrestrial decomposition and, based on evidence from multisite experiments at regional and global scales, are universally factored into global decomposition models. In contrast, soil animals are considered key regulators of decomposition at local scales but their role at larger scales is unresolved. Soil animals are consequently excluded from global models of organic mineralization processes. Incomplete assessment of the roles of soil animals stems from the difficulties of manipulating invertebrate animals experimentally across large geographic gradients. This is compounded by deficient or inconsistent taxonomy. We report a global decomposition experiment to assess the importance of soil animals in C mineralization, in which a common grass litter substrate was exposed to natural decomposition in either control or reduced animal treatments across 30 sites distributed from 43°S to 68°N on six continents. Animals in the mesofaunal size range were recovered from the litter by Tullgren extraction and identified to common specifications, mostly at the ordinal level. The design of the trials enabled faunal contribution to be evaluated against abiotic parameters between sites. Soil animals increase decomposition rates in temperate and wet tropical climates, but have neutral effects where temperature or moisture constrain biological activity. Our findings highlight that faunal influences on decomposition are dependent on prevailing climatic conditions. We conclude that (1) inclusion of soil animals will improve the predictive capabilities of region- or biome-scale decomposition models, (2) soil animal influences on decomposition are important at the regional scale when attempting to predict global change scenarios, and (3) the statistical relationship between decomposition rates and climate, at the global scale, is robust against changes in soil faunal abundance and diversity.

KW - Climate decomposition index

KW - Decomposition

KW - Litter

KW - Mesofauna

KW - Soil biodiversity

KW - Soil carbon

KW - Soil fauna

UR - https://www.scopus.com/pages/publications/54449101622

U2 - 10.1111/j.1365-2486.2008.01672.x

DO - 10.1111/j.1365-2486.2008.01672.x

M3 - Article

AN - SCOPUS:54449101622

SN - 1354-1013

VL - 14

SP - 2661

EP - 2677

JO - Global Change Biology

JF - Global Change Biology

IS - 11

ER -

Global decomposition experiment shows soil animal impacts on decomposition are climate-dependent

Abstract

UN SDGs

Keywords

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