Drought alters the carbon footprint of trees in soils—tracking the spatio‐temporal fate of (13)C‐labelled assimilates in the soil of an old‐growth pine forest

Above and belowground compartments in ecosystems are closely coupled on daily to annual timescales. In mature forests, this interlinkage and how it is impacted by drought is still poorly understood. Here, we pulse‐labelled 100‐year‐old trees with (13)CO(2) within a 15‐year‐long irrigation experiment...

Descripción completa

Detalles Bibliográficos
Autores principales: Gao, Decai, Joseph, Jobin, Werner, Roland A, Brunner, Ivano, Zürcher, Alois, Hug, Christian, Wang, Ao, Zhao, Chunhong, Bai, Edith, Meusburger, Katrin, Gessler, Arthur, Hagedorn, Frank
Formato: Online Artículo Texto
Lenguaje:English
Publicado: John Wiley and Sons Inc. 2021
Materias:
Primary Research Articles
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8251913/
https://www.ncbi.nlm.nih.gov/pubmed/33739617
http://dx.doi.org/10.1111/gcb.15557
_version_ 1783717190363512832
author Gao, Decai
Joseph, Jobin
Werner, Roland A
Brunner, Ivano
Zürcher, Alois
Hug, Christian
Wang, Ao
Zhao, Chunhong
Bai, Edith
Meusburger, Katrin
Gessler, Arthur
Hagedorn, Frank
author_facet Gao, Decai
Joseph, Jobin
Werner, Roland A
Brunner, Ivano
Zürcher, Alois
Hug, Christian
Wang, Ao
Zhao, Chunhong
Bai, Edith
Meusburger, Katrin
Gessler, Arthur
Hagedorn, Frank
author_sort Gao, Decai
collection PubMed
description Above and belowground compartments in ecosystems are closely coupled on daily to annual timescales. In mature forests, this interlinkage and how it is impacted by drought is still poorly understood. Here, we pulse‐labelled 100‐year‐old trees with (13)CO(2) within a 15‐year‐long irrigation experiment in a naturally dry pine forest to quantify how drought regime affects the transfer and use of assimilates from trees to the rhizosphere and associated microbial communities. It took 4 days until new (13)C‐labelled assimilates were allocated to the rhizosphere. One year later, the (13)C signal of the 3‐h long pulse labelling was still detectable in stem and soil respiration, which provides evidence that parts of the assimilates are stored in trees before they are used for metabolic processes in the rhizosphere. Irrigation removing the natural water stress reduced the mean C residence time from canopy uptake until soil respiration from 89 to 40 days. Moreover, irrigation increased the amount of assimilates transferred to and respired in the soil within the first 10 days by 370%. A small precipitation event rewetting surface soils altered this pattern rapidly and reduced the effect size to +35%. Microbial biomass incorporated 46 ± 5% and 31 ± 7% of the C used in the rhizosphere in the dry control and irrigation treatment respectively. Mapping the spatial distribution of soil‐respired (13)CO(2) around the 10 pulse‐labelled trees showed that tree rhizospheres extended laterally 2.8 times beyond tree canopies, implying that there is a strong overlap of the rhizosphere among adjacent trees. Irrigation increased the rhizosphere area by 60%, which gives evidence of a long‐term acclimation of trees and their rhizosphere to the drought regime. The moisture‐sensitive transfer and use of C in the rhizosphere has consequences for C allocation within trees, soil microbial communities and soil carbon storage.
format Online
Article
Text
id pubmed-8251913
institution National Center for Biotechnology Information
language English
publishDate 2021
publisher John Wiley and Sons Inc.
record_format MEDLINE/PubMed
spelling pubmed-82519132021-07-07 Drought alters the carbon footprint of trees in soils—tracking the spatio‐temporal fate of (13)C‐labelled assimilates in the soil of an old‐growth pine forest Gao, Decai Joseph, Jobin Werner, Roland A Brunner, Ivano Zürcher, Alois Hug, Christian Wang, Ao Zhao, Chunhong Bai, Edith Meusburger, Katrin Gessler, Arthur Hagedorn, Frank Glob Chang Biol Primary Research Articles Above and belowground compartments in ecosystems are closely coupled on daily to annual timescales. In mature forests, this interlinkage and how it is impacted by drought is still poorly understood. Here, we pulse‐labelled 100‐year‐old trees with (13)CO(2) within a 15‐year‐long irrigation experiment in a naturally dry pine forest to quantify how drought regime affects the transfer and use of assimilates from trees to the rhizosphere and associated microbial communities. It took 4 days until new (13)C‐labelled assimilates were allocated to the rhizosphere. One year later, the (13)C signal of the 3‐h long pulse labelling was still detectable in stem and soil respiration, which provides evidence that parts of the assimilates are stored in trees before they are used for metabolic processes in the rhizosphere. Irrigation removing the natural water stress reduced the mean C residence time from canopy uptake until soil respiration from 89 to 40 days. Moreover, irrigation increased the amount of assimilates transferred to and respired in the soil within the first 10 days by 370%. A small precipitation event rewetting surface soils altered this pattern rapidly and reduced the effect size to +35%. Microbial biomass incorporated 46 ± 5% and 31 ± 7% of the C used in the rhizosphere in the dry control and irrigation treatment respectively. Mapping the spatial distribution of soil‐respired (13)CO(2) around the 10 pulse‐labelled trees showed that tree rhizospheres extended laterally 2.8 times beyond tree canopies, implying that there is a strong overlap of the rhizosphere among adjacent trees. Irrigation increased the rhizosphere area by 60%, which gives evidence of a long‐term acclimation of trees and their rhizosphere to the drought regime. The moisture‐sensitive transfer and use of C in the rhizosphere has consequences for C allocation within trees, soil microbial communities and soil carbon storage. John Wiley and Sons Inc. 2021-03-19 2021-06 /pmc/articles/PMC8251913/ /pubmed/33739617 http://dx.doi.org/10.1111/gcb.15557 Text en © 2021 The Authors. Global Change Biology published by John Wiley & Sons Ltd. https://creativecommons.org/licenses/by-nc-nd/4.0/This is an open access article under the terms of the http://creativecommons.org/licenses/by-nc-nd/4.0/ (https://creativecommons.org/licenses/by-nc-nd/4.0/) License, which permits use and distribution in any medium, provided the original work is properly cited, the use is non‐commercial and no modifications or adaptations are made.
spellingShingle Primary Research Articles
Gao, Decai
Joseph, Jobin
Werner, Roland A
Brunner, Ivano
Zürcher, Alois
Hug, Christian
Wang, Ao
Zhao, Chunhong
Bai, Edith
Meusburger, Katrin
Gessler, Arthur
Hagedorn, Frank
Drought alters the carbon footprint of trees in soils—tracking the spatio‐temporal fate of (13)C‐labelled assimilates in the soil of an old‐growth pine forest
title Drought alters the carbon footprint of trees in soils—tracking the spatio‐temporal fate of (13)C‐labelled assimilates in the soil of an old‐growth pine forest
title_full Drought alters the carbon footprint of trees in soils—tracking the spatio‐temporal fate of (13)C‐labelled assimilates in the soil of an old‐growth pine forest
title_fullStr Drought alters the carbon footprint of trees in soils—tracking the spatio‐temporal fate of (13)C‐labelled assimilates in the soil of an old‐growth pine forest
title_full_unstemmed Drought alters the carbon footprint of trees in soils—tracking the spatio‐temporal fate of (13)C‐labelled assimilates in the soil of an old‐growth pine forest
title_short Drought alters the carbon footprint of trees in soils—tracking the spatio‐temporal fate of (13)C‐labelled assimilates in the soil of an old‐growth pine forest
title_sort drought alters the carbon footprint of trees in soils—tracking the spatio‐temporal fate of (13)c‐labelled assimilates in the soil of an old‐growth pine forest
topic Primary Research Articles
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8251913/
https://www.ncbi.nlm.nih.gov/pubmed/33739617
http://dx.doi.org/10.1111/gcb.15557
work_keys_str_mv AT gaodecai droughtaltersthecarbonfootprintoftreesinsoilstrackingthespatiotemporalfateof13clabelledassimilatesinthesoilofanoldgrowthpineforest
AT josephjobin droughtaltersthecarbonfootprintoftreesinsoilstrackingthespatiotemporalfateof13clabelledassimilatesinthesoilofanoldgrowthpineforest
AT wernerrolanda droughtaltersthecarbonfootprintoftreesinsoilstrackingthespatiotemporalfateof13clabelledassimilatesinthesoilofanoldgrowthpineforest
AT brunnerivano droughtaltersthecarbonfootprintoftreesinsoilstrackingthespatiotemporalfateof13clabelledassimilatesinthesoilofanoldgrowthpineforest
AT zurcheralois droughtaltersthecarbonfootprintoftreesinsoilstrackingthespatiotemporalfateof13clabelledassimilatesinthesoilofanoldgrowthpineforest
AT hugchristian droughtaltersthecarbonfootprintoftreesinsoilstrackingthespatiotemporalfateof13clabelledassimilatesinthesoilofanoldgrowthpineforest
AT wangao droughtaltersthecarbonfootprintoftreesinsoilstrackingthespatiotemporalfateof13clabelledassimilatesinthesoilofanoldgrowthpineforest
AT zhaochunhong droughtaltersthecarbonfootprintoftreesinsoilstrackingthespatiotemporalfateof13clabelledassimilatesinthesoilofanoldgrowthpineforest
AT baiedith droughtaltersthecarbonfootprintoftreesinsoilstrackingthespatiotemporalfateof13clabelledassimilatesinthesoilofanoldgrowthpineforest
AT meusburgerkatrin droughtaltersthecarbonfootprintoftreesinsoilstrackingthespatiotemporalfateof13clabelledassimilatesinthesoilofanoldgrowthpineforest
AT gesslerarthur droughtaltersthecarbonfootprintoftreesinsoilstrackingthespatiotemporalfateof13clabelledassimilatesinthesoilofanoldgrowthpineforest
AT hagedornfrank droughtaltersthecarbonfootprintoftreesinsoilstrackingthespatiotemporalfateof13clabelledassimilatesinthesoilofanoldgrowthpineforest

Ejemplares similares