Vegetation type and climate determine temperature thresholds of soil respiration across drylands

María Almagro; Ana Rey; Rosa M. Inclán; Josep Barba; Rodrigo Vargas; Arnaud Carrara; José M. Grünzweig; Marcelo Sternberg; Yiftach Talmon; Rebecca L. McCulley; Sara Marañón-Jiménez; Penélope Serrano-Ortiz; Javier Martínez-López; Carme Estruch; Gabriele Guidolotti; Chao Ting Chang; Joan Llovet; Mauro Lo Cascio; Jorge F. Perez-Quezada; Alexandra C. Correia; João Banza; María C. Caldeira; Carla Nogueira; Miguel N. Bugalho; Mariah S. Carbone; María Martínez-Mena; Simone Mereu; Jorge Curiel Yuste

doi:10.1016/j.soilbio.2025.109984

Vegetation type and climate determine temperature thresholds of soil respiration across drylands

María Almagro^*
, Ana Rey
, Rosa M. Inclán
, Josep Barba
, Rodrigo Vargas
, Arnaud Carrara
, José M. Grünzweig
, Marcelo Sternberg
, Yiftach Talmon
, Rebecca L. McCulley
, Sara Marañón-Jiménez
, Penélope Serrano-Ortiz
, Javier Martínez-López
, Carme Estruch
, Gabriele Guidolotti
, Chao Ting Chang
, Joan Llovet
, Mauro Lo Cascio
, Jorge F. Perez-Quezada
, Alexandra C. Correia

João Banza, María C. Caldeira, Carla Nogueira, Miguel N. Bugalho, Mariah S. Carbone, María Martínez-Mena, Simone Mereu, Jorge Curiel Yuste

^*Corresponding author for this work

Institute of Plant Sciences and Genetics in Agriculture

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

1 Scopus citations

Abstract

Soil respiration (SR) is a key component of terrestrial carbon-climate feedbacks, yet its seasonal dynamics in drylands remain poorly understood. In mesic ecosystems, SR is primarily temperature driven, whereas in drylands it shifts seasonally from temperature to moisture control as autotrophic and heterotrophic respiration become water limited during dry periods. Identifying the soil temperature at which SR transitions from temperature to moisture limitation is therefore essential for predicting SR under climate change. We examined temperature and moisture response functions of SR across forests, shrublands, and grasslands in arid and semi-arid regions to determine the soil temperature threshold of SR (STT_SR) and its drivers. Across sites, SR was positively correlated with mean annual precipitation, soil moisture, and soil organic carbon, while negatively correlated with soil temperature. The significant variability in the temperature thresholds of SR (STT_SR) that was observed between sites (17.9 °C ± 5.3 °C; mean ± SD) was best explained by the mean annual temperature (MAT) at the site. Sites with higher air temperatures exhibited higher STT_SR, suggesting that the compartments and metabolic processes involved in SR are adapted to local temperatures. This observed SR adaptation occurred at two different scales. Besides STT_SR were positively correlated with MAT within each vegetation type, STT_SR were systematically higher under short-stature vegetation types (grasslands and shrublands) compared to high-stature vegetation types (forests), suggesting that grasses and shrubs have developed the evolutionary capacity to push the STT_SR to warmer temperatures and hence withstand better drought stress than trees. Our findings suggest that: (1) process-based models assuming simple linear or exponential SR-temperature relationships overestimate SR in water-limited ecosystems; and (2) projected warming and increasing water scarcity, together with shifts in vegetation dominance, may strongly modify the temperature sensitivity of SR.

Original language	English
Article number	109984
Journal	Soil Biology and Biochemistry
Volume	211
DOIs	https://doi.org/10.1016/j.soilbio.2025.109984
State	Published - Dec 2025

Bibliographical note

Publisher Copyright:
© 2025 Elsevier Ltd

UN SDGs

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

SDG 6 Clean Water and Sanitation
SDG 13 Climate Action

Keywords

Forest
Grassland
Land-surface models
Plant and microbial community adaptation
Shrubland
Soil respiration
Soil temperature and moisture thresholds
Water-limited ecosystems

Access to Document

10.1016/j.soilbio.2025.109984

Cite this

Almagro, M., Rey, A., Inclán, R. M., Barba, J., Vargas, R., Carrara, A., Grünzweig, J. M., Sternberg, M., Talmon, Y., McCulley, R. L., Marañón-Jiménez, S., Serrano-Ortiz, P., Martínez-López, J., Estruch, C., Guidolotti, G., Chang, C. T., Llovet, J., Lo Cascio, M., Perez-Quezada, J. F., ... Curiel Yuste, J. (2025). Vegetation type and climate determine temperature thresholds of soil respiration across drylands. Soil Biology and Biochemistry, 211, Article 109984. https://doi.org/10.1016/j.soilbio.2025.109984

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title = "Vegetation type and climate determine temperature thresholds of soil respiration across drylands",

abstract = "Soil respiration (SR) is a key component of terrestrial carbon-climate feedbacks, yet its seasonal dynamics in drylands remain poorly understood. In mesic ecosystems, SR is primarily temperature driven, whereas in drylands it shifts seasonally from temperature to moisture control as autotrophic and heterotrophic respiration become water limited during dry periods. Identifying the soil temperature at which SR transitions from temperature to moisture limitation is therefore essential for predicting SR under climate change. We examined temperature and moisture response functions of SR across forests, shrublands, and grasslands in arid and semi-arid regions to determine the soil temperature threshold of SR (STTSR) and its drivers. Across sites, SR was positively correlated with mean annual precipitation, soil moisture, and soil organic carbon, while negatively correlated with soil temperature. The significant variability in the temperature thresholds of SR (STTSR) that was observed between sites (17.9 °C ± 5.3 °C; mean ± SD) was best explained by the mean annual temperature (MAT) at the site. Sites with higher air temperatures exhibited higher STTSR, suggesting that the compartments and metabolic processes involved in SR are adapted to local temperatures. This observed SR adaptation occurred at two different scales. Besides STTSR were positively correlated with MAT within each vegetation type, STTSR were systematically higher under short-stature vegetation types (grasslands and shrublands) compared to high-stature vegetation types (forests), suggesting that grasses and shrubs have developed the evolutionary capacity to push the STTSR to warmer temperatures and hence withstand better drought stress than trees. Our findings suggest that: (1) process-based models assuming simple linear or exponential SR-temperature relationships overestimate SR in water-limited ecosystems; and (2) projected warming and increasing water scarcity, together with shifts in vegetation dominance, may strongly modify the temperature sensitivity of SR.",

keywords = "Forest, Grassland, Land-surface models, Plant and microbial community adaptation, Shrubland, Soil respiration, Soil temperature and moisture thresholds, Water-limited ecosystems",

author = "Mar{\'i}a Almagro and Ana Rey and Incl{\'a}n, \{Rosa M.\} and Josep Barba and Rodrigo Vargas and Arnaud Carrara and Gr{\"u}nzweig, \{Jos{\'e} M.\} and Marcelo Sternberg and Yiftach Talmon and McCulley, \{Rebecca L.\} and Sara Mara{\~n}{\'o}n-Jim{\'e}nez and Pen{\'e}lope Serrano-Ortiz and Javier Mart{\'i}nez-L{\'o}pez and Carme Estruch and Gabriele Guidolotti and Chang, \{Chao Ting\} and Joan Llovet and \{Lo Cascio\}, Mauro and Perez-Quezada, \{Jorge F.\} and Correia, \{Alexandra C.\} and Jo{\~a}o Banza and Caldeira, \{Mar{\'i}a C.\} and Carla Nogueira and Bugalho, \{Miguel N.\} and Carbone, \{Mariah S.\} and Mar{\'i}a Mart{\'i}nez-Mena and Simone Mereu and \{Curiel Yuste\}, Jorge",

note = "Publisher Copyright: {\textcopyright} 2025 Elsevier Ltd",

year = "2025",

month = dec,

doi = "10.1016/j.soilbio.2025.109984",

language = "אנגלית",

volume = "211",

journal = "Soil Biology and Biochemistry",

issn = "0038-0717",

publisher = "Elsevier Ltd.",

}

Almagro, M, Rey, A, Inclán, RM, Barba, J, Vargas, R, Carrara, A, Grünzweig, JM, Sternberg, M, Talmon, Y, McCulley, RL, Marañón-Jiménez, S, Serrano-Ortiz, P, Martínez-López, J, Estruch, C, Guidolotti, G, Chang, CT, Llovet, J, Lo Cascio, M, Perez-Quezada, JF, Correia, AC, Banza, J, Caldeira, MC, Nogueira, C, Bugalho, MN, Carbone, MS, Martínez-Mena, M, Mereu, S & Curiel Yuste, J 2025, 'Vegetation type and climate determine temperature thresholds of soil respiration across drylands', Soil Biology and Biochemistry, vol. 211, 109984. https://doi.org/10.1016/j.soilbio.2025.109984

TY - JOUR

T1 - Vegetation type and climate determine temperature thresholds of soil respiration across drylands

AU - Almagro, María

AU - Rey, Ana

AU - Inclán, Rosa M.

AU - Barba, Josep

AU - Vargas, Rodrigo

AU - Carrara, Arnaud

AU - Grünzweig, José M.

AU - Sternberg, Marcelo

AU - Talmon, Yiftach

AU - McCulley, Rebecca L.

AU - Marañón-Jiménez, Sara

AU - Serrano-Ortiz, Penélope

AU - Martínez-López, Javier

AU - Estruch, Carme

AU - Guidolotti, Gabriele

AU - Chang, Chao Ting

AU - Llovet, Joan

AU - Lo Cascio, Mauro

AU - Perez-Quezada, Jorge F.

AU - Correia, Alexandra C.

AU - Banza, João

AU - Caldeira, María C.

AU - Nogueira, Carla

AU - Bugalho, Miguel N.

AU - Carbone, Mariah S.

AU - Martínez-Mena, María

AU - Mereu, Simone

AU - Curiel Yuste, Jorge

PY - 2025/12

Y1 - 2025/12

N2 - Soil respiration (SR) is a key component of terrestrial carbon-climate feedbacks, yet its seasonal dynamics in drylands remain poorly understood. In mesic ecosystems, SR is primarily temperature driven, whereas in drylands it shifts seasonally from temperature to moisture control as autotrophic and heterotrophic respiration become water limited during dry periods. Identifying the soil temperature at which SR transitions from temperature to moisture limitation is therefore essential for predicting SR under climate change. We examined temperature and moisture response functions of SR across forests, shrublands, and grasslands in arid and semi-arid regions to determine the soil temperature threshold of SR (STTSR) and its drivers. Across sites, SR was positively correlated with mean annual precipitation, soil moisture, and soil organic carbon, while negatively correlated with soil temperature. The significant variability in the temperature thresholds of SR (STTSR) that was observed between sites (17.9 °C ± 5.3 °C; mean ± SD) was best explained by the mean annual temperature (MAT) at the site. Sites with higher air temperatures exhibited higher STTSR, suggesting that the compartments and metabolic processes involved in SR are adapted to local temperatures. This observed SR adaptation occurred at two different scales. Besides STTSR were positively correlated with MAT within each vegetation type, STTSR were systematically higher under short-stature vegetation types (grasslands and shrublands) compared to high-stature vegetation types (forests), suggesting that grasses and shrubs have developed the evolutionary capacity to push the STTSR to warmer temperatures and hence withstand better drought stress than trees. Our findings suggest that: (1) process-based models assuming simple linear or exponential SR-temperature relationships overestimate SR in water-limited ecosystems; and (2) projected warming and increasing water scarcity, together with shifts in vegetation dominance, may strongly modify the temperature sensitivity of SR.

AB - Soil respiration (SR) is a key component of terrestrial carbon-climate feedbacks, yet its seasonal dynamics in drylands remain poorly understood. In mesic ecosystems, SR is primarily temperature driven, whereas in drylands it shifts seasonally from temperature to moisture control as autotrophic and heterotrophic respiration become water limited during dry periods. Identifying the soil temperature at which SR transitions from temperature to moisture limitation is therefore essential for predicting SR under climate change. We examined temperature and moisture response functions of SR across forests, shrublands, and grasslands in arid and semi-arid regions to determine the soil temperature threshold of SR (STTSR) and its drivers. Across sites, SR was positively correlated with mean annual precipitation, soil moisture, and soil organic carbon, while negatively correlated with soil temperature. The significant variability in the temperature thresholds of SR (STTSR) that was observed between sites (17.9 °C ± 5.3 °C; mean ± SD) was best explained by the mean annual temperature (MAT) at the site. Sites with higher air temperatures exhibited higher STTSR, suggesting that the compartments and metabolic processes involved in SR are adapted to local temperatures. This observed SR adaptation occurred at two different scales. Besides STTSR were positively correlated with MAT within each vegetation type, STTSR were systematically higher under short-stature vegetation types (grasslands and shrublands) compared to high-stature vegetation types (forests), suggesting that grasses and shrubs have developed the evolutionary capacity to push the STTSR to warmer temperatures and hence withstand better drought stress than trees. Our findings suggest that: (1) process-based models assuming simple linear or exponential SR-temperature relationships overestimate SR in water-limited ecosystems; and (2) projected warming and increasing water scarcity, together with shifts in vegetation dominance, may strongly modify the temperature sensitivity of SR.

KW - Forest

KW - Grassland

KW - Land-surface models

KW - Plant and microbial community adaptation

KW - Shrubland

KW - Soil respiration

KW - Soil temperature and moisture thresholds

KW - Water-limited ecosystems

UR - https://www.scopus.com/pages/publications/105017425443

U2 - 10.1016/j.soilbio.2025.109984

DO - 10.1016/j.soilbio.2025.109984

M3 - ???researchoutput.researchoutputtypes.contributiontojournal.article???

AN - SCOPUS:105017425443

SN - 0038-0717

VL - 211

JO - Soil Biology and Biochemistry

JF - Soil Biology and Biochemistry

M1 - 109984

ER -

Vegetation type and climate determine temperature thresholds of soil respiration across drylands

Abstract

Bibliographical note

UN SDGs

Keywords

Access to Document

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