Pan Xu, Song Yao-Bin, Jiang Can, Liu Guo-Fang, Ye Xue-Hua, Xie Xiu-Fang, Hu Yu-Kun, Zhao Wei-Wei, Cui Lijuan, Cornelissen Johannes H C, Dong Ming, Prinzing Andreas
Key Laboratory of Hangzhou City for Ecosystem Protection and Restoration, College of Life and Environmental Sciences, Hangzhou Normal University, Hangzhou, China.
Institute of Wetland Research, Chinese Academy of Forestry, Beijing, China.
PLoS One. 2015 Nov 17;10(11):e0143140. doi: 10.1371/journal.pone.0143140. eCollection 2015.
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.
植物落叶是土壤化学物质的重要来源,这些化学物质对生态系统至关重要,而落叶在分解过程中化学特性的变化将决定生态系统中多种化学元素循环的可用性。然而,目前尚不清楚是否可以分别利用其他叶片性状或落叶物种的系统发育相关性来预测分解过程中落叶化学特性的变化及其物种间的相似性。在此,我们研究了48种温带树种在不同环境条件下(在周围落叶层内/上方)1年分解过程中的破碎程度、质量损失以及10种落叶化学特性的变化,并将其与一个重要的叶片功能性状,即叶片韧性联系起来。叶片韧性在数量方面能够较好地预测变化,但在浓度方面则不然。在分解过程中,10种落叶化学特性中有7种的变化表现出显著的系统发育信号,尤其是当落叶暴露在周围落叶上方时。这些元素动态中的系统发育信号比初始元素组成的信号更强。总体而言,像分解过程中的元素动态这样相对难以测量的生态系统过程可以部分地仅从系统发育和叶片韧性测量中预测出来。我们认为,物种化学生态系统功能中强烈的系统发育信号可能反映了多个适度保守性状的协同控制,特别是当相互作用的生物群落遭受微气候压力并与周围落叶存在空间隔离时。
