TY - JOUR
T1 - Using plant traits to explain plant-microbe relationships involved in nitrogen acquisition
AU - Cantarel, Amélie A.M.
AU - Pommier, Thomas
AU - Desclos-Theveniau, Marie
AU - Diquélou, Sylvain
AU - Dumont, Maxime
AU - Grassein, Fabrice
AU - Kastl, Eva Maria
AU - Grigulis, Karl
AU - Laîné, Philippe
AU - Lavorel, Sandra
AU - Lemauviel-Lavenant, Servane
AU - Personeni, Emmanuelle
AU - Schloter, Michael
AU - Poly, Franck
N1 - Publisher Copyright:
© 2015 by the Ecological Society of America.
PY - 2015/3/1
Y1 - 2015/3/1
N2 - It has long been recognized that plant species and soil microorganisms are tightly linked, but understanding how different species vary in their effects on soil is currently limited. In this study, we identified those plant characteristics (identity, specific functional traits, or resource acquisition strategy) that were the best predictors of nitrification and denitrification processes. Ten plant populations representing eight species collected from three European grassland sites were chosen for their contrasting plant trait values and resource acquisition strategies. For each individual plant, leaf and root traits and the associated potential microbial activities (i.e., potential denitrification rate [DEA], maximal nitrification rate [NEA], and NH4+ affinity of the microbial community [NHScom]) were measured at two fertilization levels under controlled growth conditions. Plant traits were powerful predictors of plant-microbe interactions, but relevant plant traits differed in relation to the microbial function studied. Whereas denitrification was linked to the relative growth rate of plants, nitrification was strongly correlated to root trait characteristics (specific root length, root nitrogen concentration, and plant affinity for NH4+) linked to plant N cycling. The leaf economics spectrum (LES) that commonly serves as an indicator of resource acquisition strategies was not correlated to microbial activity. These results suggest that the LES alone is not a good predictor of microbial activity, whereas root traits appeared critical in understanding plant-microbe interactions.
AB - It has long been recognized that plant species and soil microorganisms are tightly linked, but understanding how different species vary in their effects on soil is currently limited. In this study, we identified those plant characteristics (identity, specific functional traits, or resource acquisition strategy) that were the best predictors of nitrification and denitrification processes. Ten plant populations representing eight species collected from three European grassland sites were chosen for their contrasting plant trait values and resource acquisition strategies. For each individual plant, leaf and root traits and the associated potential microbial activities (i.e., potential denitrification rate [DEA], maximal nitrification rate [NEA], and NH4+ affinity of the microbial community [NHScom]) were measured at two fertilization levels under controlled growth conditions. Plant traits were powerful predictors of plant-microbe interactions, but relevant plant traits differed in relation to the microbial function studied. Whereas denitrification was linked to the relative growth rate of plants, nitrification was strongly correlated to root trait characteristics (specific root length, root nitrogen concentration, and plant affinity for NH4+) linked to plant N cycling. The leaf economics spectrum (LES) that commonly serves as an indicator of resource acquisition strategies was not correlated to microbial activity. These results suggest that the LES alone is not a good predictor of microbial activity, whereas root traits appeared critical in understanding plant-microbe interactions.
KW - Denitrification
KW - Leaf economics spectrum
KW - Nitrification
KW - Plant strategy for N resource acquisition
KW - Plant traits
KW - Rhizosphere
UR - http://www.scopus.com/inward/record.url?scp=84929660770&partnerID=8YFLogxK
U2 - 10.1890/13-2107.1
DO - 10.1890/13-2107.1
M3 - Article
C2 - 26236874
AN - SCOPUS:84929660770
SN - 0012-9658
VL - 96
SP - 788
EP - 799
JO - Ecology
JF - Ecology
IS - 3
ER -