Peatland warming strongly increases fine-root growth

Avni Malhotra; Deanne J. Brice; Joanne Childs; Jake D. Graham; Erik A. Hobbie; Holly Vander Stel; Sarah C. Feron; Paul J. Hanson; Colleen M. Iversen

doi:10.1073/pnas.2003361117

Peatland warming strongly increases fine-root growth

Avni Malhotra, Deanne J. Brice, Joanne Childs, Jake D. Graham, Erik A. Hobbie, Holly Vander Stel, Sarah C. Feron, Paul J. Hanson, Colleen M. Iversen

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

107 Scopus citations

Abstract

Belowground climate change responses remain a key unknown in the Earth system. Plant fine-root response is especially important to understand because fine roots respond quickly to environmental change, are responsible for nutrient and water uptake, and influence carbon cycling. However, fine-root responses to climate change are poorly constrained, especially in northern peatlands, which contain up to two-thirds of the world’s soil carbon. We present fine-root responses to warming between +2 °C and 9 °C above ambient conditions in a whole-ecosystem peatland experiment. Warming strongly increased fine-root growth by over an order of magnitude in the warmest treatment, with stronger responses in shrubs than in trees or graminoids. In the first year of treatment, the control (+0 °C) shrub fine-root growth of 0.9 km m^-2 y^-1 increased linearly by 1.2 km m^-2 y^-1 (130%) for every degree increase in soil temperature. An extended belowground growing season accounted for 20% of this dramatic increase. In the second growing season of treatment, the shrub warming response rate increased to 2.54 km m^-2 °C^-1. Soil moisture was negatively correlated with fine-root growth, highlighting that drying of these typically water-saturated ecosystems can fuel a surprising burst in shrub belowground productivity, one possible mechanism explaining the “shrubification” of northern peatlands in response to global change. This previously unrecognized mechanism sheds light on how peatland fine-root response to warming and drying could be strong and rapid, with consequences for the belowground growing season duration, microtopography, vegetation composition, and ultimately, carbon function of these globally relevant carbon sinks.

Original language	English
Pages (from-to)	17627-17634
Number of pages	8
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	117
Issue number	30
DOIs	https://doi.org/10.1073/pnas.2003361117
State	Published - Jul 28 2020

Funding

ACKNOWLEDGMENTS. We thank A. Shafer Powell, Logan Owens, Sarah Bellaire, Lindsey Rasnake, Emily Kraeske, Stephanie Letourneau, and Les Hook for help with field work, sample processing, and data availability. We also thank Verity Salmon and Natalie Griffiths for comments on early versions of the manuscript. The SPRUCE experiment is supported by the Office of Biological and Environmental Research in the US Department of Energy’s Office of Science. J.D.G. was supported under Contract 4000145196 between Oak Ridge National Laboratory and Boise State University with funding for the SPRUCE project from the US Department of Energy. S.C.F. acknowledges the support of Corporación de Fomento de la Producción (CORFO) 19BP-117358 & 18BPE-93920. This manuscript has been authored by UT-Battelle, LLC under Contract DE-AC05-00OR22725 with the US Department of Energy. The We thank A. Shafer Powell, Logan Owens, Sarah Bellaire, Lindsey Rasnake, Emily Kraeske, Stephanie Letourneau, and Les Hook for help with field work, sample processing, and data availability. We also thank Verity Salmon and Natalie Griffiths for comments on early versions of the manuscript. The SPRUCE experiment is supported by the Office of Biological and Environmental Research in the US Department of Energy?s Office of Science. J.D.G. was supported under Contract 4000145196 between Oak Ridge National Laboratory and Boise State University with funding for the SPRUCE project from the US Department of Energy. S.C.F. acknowledges the support of Corporaci?n de Fomento de la Producci?n (CORFO) 19BP-117358 & 18BPE-93920. This manuscript has been authored by UT-Battelle, LLC under Contract DE-AC05-00OR22725 with the US Department of Energy. The US Government retains and the publisher, by accepting the article for publication, acknowledges that the US Government retains a nonexclusive, paid-up, irrevocable, worldwide license to publish or reproduce the published form of this manuscript, or allow others to do so, for US Government purposes. The Department of Energy will provide public access to these results of federally sponsored research in accordance with the Department of Energy Public Access Plan (https://www.energy.gov/downloads/doe-public-access-plan).

Keywords

Belowground plant response
Elevated carbon dioxide
Experimental warming
Fine roots
Peatland

UN SDGs

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

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10.1073/pnas.2003361117

Cite this

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title = "Peatland warming strongly increases fine-root growth",

abstract = "Belowground climate change responses remain a key unknown in the Earth system. Plant fine-root response is especially important to understand because fine roots respond quickly to environmental change, are responsible for nutrient and water uptake, and influence carbon cycling. However, fine-root responses to climate change are poorly constrained, especially in northern peatlands, which contain up to two-thirds of the world{\textquoteright}s soil carbon. We present fine-root responses to warming between +2 °C and 9 °C above ambient conditions in a whole-ecosystem peatland experiment. Warming strongly increased fine-root growth by over an order of magnitude in the warmest treatment, with stronger responses in shrubs than in trees or graminoids. In the first year of treatment, the control (+0 °C) shrub fine-root growth of 0.9 km m-2 y-1 increased linearly by 1.2 km m-2 y-1 (130%) for every degree increase in soil temperature. An extended belowground growing season accounted for 20% of this dramatic increase. In the second growing season of treatment, the shrub warming response rate increased to 2.54 km m-2 °C-1. Soil moisture was negatively correlated with fine-root growth, highlighting that drying of these typically water-saturated ecosystems can fuel a surprising burst in shrub belowground productivity, one possible mechanism explaining the “shrubification” of northern peatlands in response to global change. This previously unrecognized mechanism sheds light on how peatland fine-root response to warming and drying could be strong and rapid, with consequences for the belowground growing season duration, microtopography, vegetation composition, and ultimately, carbon function of these globally relevant carbon sinks.",

keywords = "Belowground plant response, Elevated carbon dioxide, Experimental warming, Fine roots, Peatland",

author = "Avni Malhotra and Brice, {Deanne J.} and Joanne Childs and Graham, {Jake D.} and Hobbie, {Erik A.} and {Vander Stel}, Holly and Feron, {Sarah C.} and Hanson, {Paul J.} and Iversen, {Colleen M.}",

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T1 - Peatland warming strongly increases fine-root growth

AU - Malhotra, Avni

AU - Brice, Deanne J.

AU - Childs, Joanne

AU - Graham, Jake D.

AU - Hobbie, Erik A.

AU - Vander Stel, Holly

AU - Feron, Sarah C.

AU - Hanson, Paul J.

AU - Iversen, Colleen M.

PY - 2020/7/28

Y1 - 2020/7/28

N2 - Belowground climate change responses remain a key unknown in the Earth system. Plant fine-root response is especially important to understand because fine roots respond quickly to environmental change, are responsible for nutrient and water uptake, and influence carbon cycling. However, fine-root responses to climate change are poorly constrained, especially in northern peatlands, which contain up to two-thirds of the world’s soil carbon. We present fine-root responses to warming between +2 °C and 9 °C above ambient conditions in a whole-ecosystem peatland experiment. Warming strongly increased fine-root growth by over an order of magnitude in the warmest treatment, with stronger responses in shrubs than in trees or graminoids. In the first year of treatment, the control (+0 °C) shrub fine-root growth of 0.9 km m-2 y-1 increased linearly by 1.2 km m-2 y-1 (130%) for every degree increase in soil temperature. An extended belowground growing season accounted for 20% of this dramatic increase. In the second growing season of treatment, the shrub warming response rate increased to 2.54 km m-2 °C-1. Soil moisture was negatively correlated with fine-root growth, highlighting that drying of these typically water-saturated ecosystems can fuel a surprising burst in shrub belowground productivity, one possible mechanism explaining the “shrubification” of northern peatlands in response to global change. This previously unrecognized mechanism sheds light on how peatland fine-root response to warming and drying could be strong and rapid, with consequences for the belowground growing season duration, microtopography, vegetation composition, and ultimately, carbon function of these globally relevant carbon sinks.

AB - Belowground climate change responses remain a key unknown in the Earth system. Plant fine-root response is especially important to understand because fine roots respond quickly to environmental change, are responsible for nutrient and water uptake, and influence carbon cycling. However, fine-root responses to climate change are poorly constrained, especially in northern peatlands, which contain up to two-thirds of the world’s soil carbon. We present fine-root responses to warming between +2 °C and 9 °C above ambient conditions in a whole-ecosystem peatland experiment. Warming strongly increased fine-root growth by over an order of magnitude in the warmest treatment, with stronger responses in shrubs than in trees or graminoids. In the first year of treatment, the control (+0 °C) shrub fine-root growth of 0.9 km m-2 y-1 increased linearly by 1.2 km m-2 y-1 (130%) for every degree increase in soil temperature. An extended belowground growing season accounted for 20% of this dramatic increase. In the second growing season of treatment, the shrub warming response rate increased to 2.54 km m-2 °C-1. Soil moisture was negatively correlated with fine-root growth, highlighting that drying of these typically water-saturated ecosystems can fuel a surprising burst in shrub belowground productivity, one possible mechanism explaining the “shrubification” of northern peatlands in response to global change. This previously unrecognized mechanism sheds light on how peatland fine-root response to warming and drying could be strong and rapid, with consequences for the belowground growing season duration, microtopography, vegetation composition, and ultimately, carbon function of these globally relevant carbon sinks.

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KW - Elevated carbon dioxide

KW - Experimental warming

KW - Fine roots

KW - Peatland

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EP - 17634

JO - Proceedings of the National Academy of Sciences of the United States of America

JF - Proceedings of the National Academy of Sciences of the United States of America

IS - 30

ER -

Peatland warming strongly increases fine-root growth

Abstract

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Keywords

UN SDGs

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