TY - JOUR
T1 - Fungal community composition predicts forest carbon storage at a continental scale
AU - Anthony, Mark A.
AU - Tedersoo, Leho
AU - De Vos, Bruno
AU - Croisé, Luc
AU - Meesenburg, Henning
AU - Wagner, Markus
AU - Andreae, Henning
AU - Jacob, Frank
AU - Lech, Paweł
AU - Kowalska, Anna
AU - Greve, Martin
AU - Popova, Genoveva
AU - Frey, Beat
AU - Gessler, Arthur
AU - Schaub, Marcus
AU - Ferretti, Marco
AU - Waldner, Peter
AU - Calatayud, Vicent
AU - Canullo, Roberto
AU - Papitto, Giancarlo
AU - Marinšek, Aleksander
AU - Ingerslev, Morten
AU - Vesterdal, Lars
AU - Rautio, Pasi
AU - Meissner, Helge
AU - Timmermann, Volkmar
AU - Dettwiler, Mike
AU - Eickenscheidt, Nadine
AU - Schmitz, Andreas
AU - Van Tiel, Nina
AU - Crowther, Thomas W.
AU - Averill, Colin
N1 - Publisher Copyright:
© The Author(s) 2024.
PY - 2024
Y1 - 2024
N2 - Forest soils harbor hyper-diverse microbial communities which fundamentally regulate carbon and nutrient cycling across the globe. Directly testing hypotheses on how microbiome diversity is linked to forest carbon storage has been difficult, due to a lack of paired data on microbiome diversity and in situ observations of forest carbon accumulation and storage. Here, we investigated the relationship between soil microbiomes and forest carbon across 238 forest inventory plots spanning 15 European countries. We show that the composition and diversity of fungal, but not bacterial, species is tightly coupled to both forest biotic conditions and a seven-fold variation in tree growth rates and biomass carbon stocks when controlling for the effects of dominant tree type, climate, and other environmental factors. This linkage is particularly strong for symbiotic endophytic and ectomycorrhizal fungi known to directly facilitate tree growth. Since tree growth rates in this system are closely and positively correlated with belowground soil carbon stocks, we conclude that fungal composition is a strong predictor of overall forest carbon storage across the European continent.
AB - Forest soils harbor hyper-diverse microbial communities which fundamentally regulate carbon and nutrient cycling across the globe. Directly testing hypotheses on how microbiome diversity is linked to forest carbon storage has been difficult, due to a lack of paired data on microbiome diversity and in situ observations of forest carbon accumulation and storage. Here, we investigated the relationship between soil microbiomes and forest carbon across 238 forest inventory plots spanning 15 European countries. We show that the composition and diversity of fungal, but not bacterial, species is tightly coupled to both forest biotic conditions and a seven-fold variation in tree growth rates and biomass carbon stocks when controlling for the effects of dominant tree type, climate, and other environmental factors. This linkage is particularly strong for symbiotic endophytic and ectomycorrhizal fungi known to directly facilitate tree growth. Since tree growth rates in this system are closely and positively correlated with belowground soil carbon stocks, we conclude that fungal composition is a strong predictor of overall forest carbon storage across the European continent.
U2 - 10.1038/s41467-024-46792-w
DO - 10.1038/s41467-024-46792-w
M3 - Journal article
C2 - 38493170
AN - SCOPUS:85187949395
VL - 15
JO - Nature Communications
JF - Nature Communications
SN - 2041-1723
M1 - 2385
ER -