Evolutionary Position and Leaf Toughness Control Chemical Transformation of Litter, and Drought Reinforces This Control: Evidence from a Common Garden Experiment across 48 Species.

Evolutionary Position and Leaf Toughness Control Chemical Transformation of Litter, and Drought Reinforces This Control: Evidence from a Common Garden Experiment across 48 Species.

Plant leaf litter is an important source of soil chemicals that are essential for the ecosystem and changes in leaf litter chemical traits during decomposition will determine the availability of multiple chemical elements recycling in the ecosystem. However, it is unclear whether the changes in litt...

Full description

Bibliographic Details
Main Authors: Xu Pan, Yao-Bin Song, Can Jiang, Guo-Fang Liu, Xue-Hua Ye, Xiu-Fang Xie, Yu-Kun Hu, Wei-Wei Zhao, Lijuan Cui, Johannes H C Cornelissen, Ming Dong, Andreas Prinzing
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2015-01-01
Series:PLoS ONE
Online Access:http://europepmc.org/articles/PMC4648592?pdf=render
id doaj-9569751097234cbb85e9c2264cb459f7
record_format Article
spelling doaj-9569751097234cbb85e9c2264cb459f72020-11-25T01:22:07ZengPublic Library of Science (PLoS)PLoS ONE1932-62032015-01-011011e014314010.1371/journal.pone.0143140Evolutionary Position and Leaf Toughness Control Chemical Transformation of Litter, and Drought Reinforces This Control: Evidence from a Common Garden Experiment across 48 Species.Xu PanYao-Bin SongCan JiangGuo-Fang LiuXue-Hua YeXiu-Fang XieYu-Kun HuWei-Wei ZhaoLijuan CuiJohannes H C CornelissenMing DongAndreas PrinzingPlant leaf litter is an important source of soil chemicals that are essential for the ecosystem and changes in leaf litter chemical traits during decomposition will determine the availability of multiple chemical elements recycling in the ecosystem. However, it is unclear whether the changes in litter chemical traits during decomposition and their similarities across species can be predicted, respectively, using other leaf traits or using the phylogenetic relatedness of the litter species. Here we examined the fragmentation levels, mass losses, and the changes of 10 litter chemical traits during 1-yr decomposition under different environmental conditions (within/above surrounding litter layer) for 48 temperate tree species and related them to an important leaf functional trait, i.e. leaf toughness. Leaf toughness could predict the changes well in terms of amounts, but poorly in terms of concentrations. Changes of 7 out of 10 litter chemical traits during decomposition showed a significant phylogenetic signal notably when litter was exposed above surrounding litter. These phylogenetic signals in element dynamics were stronger than those of initial elementary composition. Overall, relatively hard-to-measure ecosystem processes like element dynamics during decomposition could be partly predicted simply from phylogenies and leaf toughness measures. We suggest that the strong phylogenetic signals in chemical ecosystem functioning of species may reflect the concerted control by multiple moderately conserved traits, notably if interacting biota suffer microclimatic stress and spatial isolation from ambient litter.http://europepmc.org/articles/PMC4648592?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Xu Pan
Yao-Bin Song
Can Jiang
Guo-Fang Liu
Xue-Hua Ye
Xiu-Fang Xie
Yu-Kun Hu
Wei-Wei Zhao
Lijuan Cui
Johannes H C Cornelissen
Ming Dong
Andreas Prinzing
spellingShingle Xu Pan
Yao-Bin Song
Can Jiang
Guo-Fang Liu
Xue-Hua Ye
Xiu-Fang Xie
Yu-Kun Hu
Wei-Wei Zhao
Lijuan Cui
Johannes H C Cornelissen
Ming Dong
Andreas Prinzing
Evolutionary Position and Leaf Toughness Control Chemical Transformation of Litter, and Drought Reinforces This Control: Evidence from a Common Garden Experiment across 48 Species.
PLoS ONE
author_facet Xu Pan
Yao-Bin Song
Can Jiang
Guo-Fang Liu
Xue-Hua Ye
Xiu-Fang Xie
Yu-Kun Hu
Wei-Wei Zhao
Lijuan Cui
Johannes H C Cornelissen
Ming Dong
Andreas Prinzing
author_sort Xu Pan
title Evolutionary Position and Leaf Toughness Control Chemical Transformation of Litter, and Drought Reinforces This Control: Evidence from a Common Garden Experiment across 48 Species.
title_short Evolutionary Position and Leaf Toughness Control Chemical Transformation of Litter, and Drought Reinforces This Control: Evidence from a Common Garden Experiment across 48 Species.
title_full Evolutionary Position and Leaf Toughness Control Chemical Transformation of Litter, and Drought Reinforces This Control: Evidence from a Common Garden Experiment across 48 Species.
title_fullStr Evolutionary Position and Leaf Toughness Control Chemical Transformation of Litter, and Drought Reinforces This Control: Evidence from a Common Garden Experiment across 48 Species.
title_full_unstemmed Evolutionary Position and Leaf Toughness Control Chemical Transformation of Litter, and Drought Reinforces This Control: Evidence from a Common Garden Experiment across 48 Species.
title_sort evolutionary position and leaf toughness control chemical transformation of litter, and drought reinforces this control: evidence from a common garden experiment across 48 species.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2015-01-01
description Plant leaf litter is an important source of soil chemicals that are essential for the ecosystem and changes in leaf litter chemical traits during decomposition will determine the availability of multiple chemical elements recycling in the ecosystem. However, it is unclear whether the changes in litter chemical traits during decomposition and their similarities across species can be predicted, respectively, using other leaf traits or using the phylogenetic relatedness of the litter species. Here we examined the fragmentation levels, mass losses, and the changes of 10 litter chemical traits during 1-yr decomposition under different environmental conditions (within/above surrounding litter layer) for 48 temperate tree species and related them to an important leaf functional trait, i.e. leaf toughness. Leaf toughness could predict the changes well in terms of amounts, but poorly in terms of concentrations. Changes of 7 out of 10 litter chemical traits during decomposition showed a significant phylogenetic signal notably when litter was exposed above surrounding litter. These phylogenetic signals in element dynamics were stronger than those of initial elementary composition. Overall, relatively hard-to-measure ecosystem processes like element dynamics during decomposition could be partly predicted simply from phylogenies and leaf toughness measures. We suggest that the strong phylogenetic signals in chemical ecosystem functioning of species may reflect the concerted control by multiple moderately conserved traits, notably if interacting biota suffer microclimatic stress and spatial isolation from ambient litter.
url http://europepmc.org/articles/PMC4648592?pdf=render
work_keys_str_mv AT xupan evolutionarypositionandleaftoughnesscontrolchemicaltransformationoflitteranddroughtreinforcesthiscontrolevidencefromacommongardenexperimentacross48species
AT yaobinsong evolutionarypositionandleaftoughnesscontrolchemicaltransformationoflitteranddroughtreinforcesthiscontrolevidencefromacommongardenexperimentacross48species
AT canjiang evolutionarypositionandleaftoughnesscontrolchemicaltransformationoflitteranddroughtreinforcesthiscontrolevidencefromacommongardenexperimentacross48species
AT guofangliu evolutionarypositionandleaftoughnesscontrolchemicaltransformationoflitteranddroughtreinforcesthiscontrolevidencefromacommongardenexperimentacross48species
AT xuehuaye evolutionarypositionandleaftoughnesscontrolchemicaltransformationoflitteranddroughtreinforcesthiscontrolevidencefromacommongardenexperimentacross48species
AT xiufangxie evolutionarypositionandleaftoughnesscontrolchemicaltransformationoflitteranddroughtreinforcesthiscontrolevidencefromacommongardenexperimentacross48species
AT yukunhu evolutionarypositionandleaftoughnesscontrolchemicaltransformationoflitteranddroughtreinforcesthiscontrolevidencefromacommongardenexperimentacross48species
AT weiweizhao evolutionarypositionandleaftoughnesscontrolchemicaltransformationoflitteranddroughtreinforcesthiscontrolevidencefromacommongardenexperimentacross48species
AT lijuancui evolutionarypositionandleaftoughnesscontrolchemicaltransformationoflitteranddroughtreinforcesthiscontrolevidencefromacommongardenexperimentacross48species
AT johanneshccornelissen evolutionarypositionandleaftoughnesscontrolchemicaltransformationoflitteranddroughtreinforcesthiscontrolevidencefromacommongardenexperimentacross48species
AT mingdong evolutionarypositionandleaftoughnesscontrolchemicaltransformationoflitteranddroughtreinforcesthiscontrolevidencefromacommongardenexperimentacross48species
AT andreasprinzing evolutionarypositionandleaftoughnesscontrolchemicaltransformationoflitteranddroughtreinforcesthiscontrolevidencefromacommongardenexperimentacross48species
_version_ 1725127711497650176

Similar Items