Combined effects of warming and drought on plant biomass depend on plant woodiness and community type: a meta-analysis

Rutger A. Wilschut; Jonathan R. De Long; Stefan Geisen; S. Emilia Hannula; Casper W. Quist; Basten Snoek; Katja Steinauer; E. R.Jasper Wubs; Qiang Yang; Madhav P. Thakur

doi:10.1098/rspb.2022.1178

Combined effects of warming and drought on plant biomass depend on plant woodiness and community type: a meta-analysis

Rutger A. Wilschut^* (Corresponding author), Jonathan R. De Long, Stefan Geisen, S. Emilia Hannula, Casper W. Quist, Basten Snoek, Katja Steinauer, E. R.Jasper Wubs, Qiang Yang, Madhav P. Thakur

^*Corresponding author for this work

NIOO - Terrestrial Ecology (TE)

Research output: Contribution to journal/periodical › Article › Scientific › peer-review

Abstract

Global warming and precipitation extremes (drought or increased precipitation) strongly affect plant primary production and thereby terrestrial ecosystem functioning. Recent syntheses show that combined effects of warming and precipitation extremes on plant biomass are generally additive, while individual experiments often show interactive effects, indicating that combined effects are more negative or positive than expected based on the effects of single factors. Here, we examined whether variation in biomass responses to single and combined effects of warming and precipitation extremes can be explained by plant growth form and community type. We performed a meta-analysis of 37 studies, which experimentally crossed warming and precipitation treatments, to test whether biomass responses to combined effects of warming and precipitation extremes depended on plant woodiness and community type (monocultures versus mixtures). Our results confirmed that the effects of warming and precipitation extremes were overall additive. However, combined effects of warming and drought on above- and belowground biomass were less negative in woody- than in herbaceous plant systems and more negative in plant mixtures than in monocultures. We further show that drought effects on plant biomass were more negative in greenhouse- than in field studies, suggesting that greenhouse experiments may overstate drought effects in the field. Our results highlight the importance of plant system characteristics to better understand plant responses to climate change.

Original language	English
Article number	20221178
Journal	Proceedings of the Royal Society B: Biological Sciences
Volume	289
Issue number	1984
DOIs	https://doi.org/10.1098/rspb.2022.1178
Publication status	Published - 2022

Keywords

aboveground plant biomass
belowground plant biomass
climate warming
global change experiments
precipitation decrease
precipitation increase

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10.1098/rspb.2022.1178Licence: CC BY

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Wilschut, R. A., De Long, J. R., Geisen, S., Hannula, S. E., Quist, C. W., Snoek, B., Steinauer, K., Wubs, E. R. J., Yang, Q., & Thakur, M. P. (2022). Combined effects of warming and drought on plant biomass depend on plant woodiness and community type: a meta-analysis. Proceedings of the Royal Society B: Biological Sciences, 289(1984), [20221178]. https://doi.org/10.1098/rspb.2022.1178

Wilschut, Rutger A. ; De Long, Jonathan R. ; Geisen, Stefan ; Hannula, S. Emilia ; Quist, Casper W. ; Snoek, Basten ; Steinauer, Katja ; Wubs, E. R.Jasper ; Yang, Qiang ; Thakur, Madhav P. / Combined effects of warming and drought on plant biomass depend on plant woodiness and community type : a meta-analysis. In: Proceedings of the Royal Society B: Biological Sciences. 2022 ; Vol. 289, No. 1984.

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title = "Combined effects of warming and drought on plant biomass depend on plant woodiness and community type: a meta-analysis",

abstract = "Global warming and precipitation extremes (drought or increased precipitation) strongly affect plant primary production and thereby terrestrial ecosystem functioning. Recent syntheses show that combined effects of warming and precipitation extremes on plant biomass are generally additive, while individual experiments often show interactive effects, indicating that combined effects are more negative or positive than expected based on the effects of single factors. Here, we examined whether variation in biomass responses to single and combined effects of warming and precipitation extremes can be explained by plant growth form and community type. We performed a meta-analysis of 37 studies, which experimentally crossed warming and precipitation treatments, to test whether biomass responses to combined effects of warming and precipitation extremes depended on plant woodiness and community type (monocultures versus mixtures). Our results confirmed that the effects of warming and precipitation extremes were overall additive. However, combined effects of warming and drought on above- and belowground biomass were less negative in woody- than in herbaceous plant systems and more negative in plant mixtures than in monocultures. We further show that drought effects on plant biomass were more negative in greenhouse- than in field studies, suggesting that greenhouse experiments may overstate drought effects in the field. Our results highlight the importance of plant system characteristics to better understand plant responses to climate change.",

keywords = "aboveground plant biomass, belowground plant biomass, climate warming, global change experiments, precipitation decrease, precipitation increase",

author = "Wilschut, {Rutger A.} and {De Long}, {Jonathan R.} and Stefan Geisen and Hannula, {S. Emilia} and Quist, {Casper W.} and Basten Snoek and Katja Steinauer and Wubs, {E. R.Jasper} and Qiang Yang and Thakur, {Madhav P.}",

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Wilschut, RA, De Long, JR, Geisen, S, Hannula, SE, Quist, CW, Snoek, B, Steinauer, K, Wubs, ERJ, Yang, Q & Thakur, MP 2022, 'Combined effects of warming and drought on plant biomass depend on plant woodiness and community type: a meta-analysis', Proceedings of the Royal Society B: Biological Sciences, vol. 289, no. 1984, 20221178. https://doi.org/10.1098/rspb.2022.1178

Combined effects of warming and drought on plant biomass depend on plant woodiness and community type : a meta-analysis. / Wilschut, Rutger A. (Corresponding author); De Long, Jonathan R.; Geisen, Stefan; Hannula, S. Emilia; Quist, Casper W.; Snoek, Basten; Steinauer, Katja; Wubs, E. R.Jasper; Yang, Qiang; Thakur, Madhav P.

In: Proceedings of the Royal Society B: Biological Sciences, Vol. 289, No. 1984, 20221178, 2022.

Research output: Contribution to journal/periodical › Article › Scientific › peer-review

TY - JOUR

T1 - Combined effects of warming and drought on plant biomass depend on plant woodiness and community type

T2 - a meta-analysis

AU - Wilschut, Rutger A.

AU - De Long, Jonathan R.

AU - Geisen, Stefan

AU - Hannula, S. Emilia

AU - Quist, Casper W.

AU - Snoek, Basten

AU - Steinauer, Katja

AU - Wubs, E. R.Jasper

AU - Yang, Qiang

AU - Thakur, Madhav P.

N1 - 7642, TE

PY - 2022

Y1 - 2022

N2 - Global warming and precipitation extremes (drought or increased precipitation) strongly affect plant primary production and thereby terrestrial ecosystem functioning. Recent syntheses show that combined effects of warming and precipitation extremes on plant biomass are generally additive, while individual experiments often show interactive effects, indicating that combined effects are more negative or positive than expected based on the effects of single factors. Here, we examined whether variation in biomass responses to single and combined effects of warming and precipitation extremes can be explained by plant growth form and community type. We performed a meta-analysis of 37 studies, which experimentally crossed warming and precipitation treatments, to test whether biomass responses to combined effects of warming and precipitation extremes depended on plant woodiness and community type (monocultures versus mixtures). Our results confirmed that the effects of warming and precipitation extremes were overall additive. However, combined effects of warming and drought on above- and belowground biomass were less negative in woody- than in herbaceous plant systems and more negative in plant mixtures than in monocultures. We further show that drought effects on plant biomass were more negative in greenhouse- than in field studies, suggesting that greenhouse experiments may overstate drought effects in the field. Our results highlight the importance of plant system characteristics to better understand plant responses to climate change.

AB - Global warming and precipitation extremes (drought or increased precipitation) strongly affect plant primary production and thereby terrestrial ecosystem functioning. Recent syntheses show that combined effects of warming and precipitation extremes on plant biomass are generally additive, while individual experiments often show interactive effects, indicating that combined effects are more negative or positive than expected based on the effects of single factors. Here, we examined whether variation in biomass responses to single and combined effects of warming and precipitation extremes can be explained by plant growth form and community type. We performed a meta-analysis of 37 studies, which experimentally crossed warming and precipitation treatments, to test whether biomass responses to combined effects of warming and precipitation extremes depended on plant woodiness and community type (monocultures versus mixtures). Our results confirmed that the effects of warming and precipitation extremes were overall additive. However, combined effects of warming and drought on above- and belowground biomass were less negative in woody- than in herbaceous plant systems and more negative in plant mixtures than in monocultures. We further show that drought effects on plant biomass were more negative in greenhouse- than in field studies, suggesting that greenhouse experiments may overstate drought effects in the field. Our results highlight the importance of plant system characteristics to better understand plant responses to climate change.

KW - aboveground plant biomass

KW - belowground plant biomass

KW - climate warming

KW - global change experiments

KW - precipitation decrease

KW - precipitation increase

U2 - 10.1098/rspb.2022.1178

DO - 10.1098/rspb.2022.1178

M3 - Article

C2 - 36196543

AN - SCOPUS:85139573400

VL - 289

JO - Proceedings of the Royal Society B-Biological Sciences

JF - Proceedings of the Royal Society B-Biological Sciences

SN - 0962-8452

IS - 1984

M1 - 20221178

ER -

Combined effects of warming and drought on plant biomass depend on plant woodiness and community type: a meta-analysis

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Keywords

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