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欧洲酸性磷酸酶活性的空间格局与环境驱动因素

Spatial Pattern and Environmental Drivers of Acid Phosphatase Activity in Europe.

作者信息

Sun Yan, Goll Daniel S, Ciais Philippe, Peng Shushi, Margalef Olga, Asensio Dolores, Sardans Jordi, Peñuelas Josep

机构信息

Laboratoire des Sciences du Climat et de 1'Environnement, CEA-CNRS-UVSQ, Gif sur Yvette, France.

Institute of Geography, University of Augsburg, Augsburg, Germany.

出版信息

Front Big Data. 2020 Jan 23;2:51. doi: 10.3389/fdata.2019.00051. eCollection 2019.

DOI:10.3389/fdata.2019.00051
PMID:33693374
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7931918/
Abstract

Acid phosphatase produced by plants and microbes plays a fundamental role in the recycling of soil phosphorus (P). A quantification of the spatial variation in potential acid phosphatase activity (AP) on large spatial scales and its drivers can help to reduce the uncertainty in our understanding of bio-availability of soil P. We applied two machine-learning methods (Random forests and back-propagation artificial networks) to simulate the spatial patterns of AP across Europe by scaling up 126 site observations of potential AP activity from field samples measured in the laboratory, using 12 environmental drivers as predictors. The back-propagation artificial network (BPN) method explained 58% of AP variability, more than the regression tree model (49%). In addition, BPN was able to identify the gradients in AP along three transects in Europe. Partial correlation analysis revealed that soil nutrients (total nitrogen, total P, and labile organic P) and climatic controls (annual precipitation, mean annual temperature, and temperature amplitude) were the dominant factors influencing AP variations in space. Higher AP occurred in regions with higher mean annual temperature, precipitation and higher soil total nitrogen. Soil TP and Po were non-monotonically correlated with modeled AP for Europe, indicating diffident strategies of P utilization by biomes in arid and humid area. This study helps to separate the influences of each factor on AP production and to reduce the uncertainty in estimating soil P availability. The BPN model trained with European data, however, could not produce a robust global map of AP due to the lack of representative measurements of AP for tropical regions. Filling this data gap will help us to understand the physiological basis of P-use strategies in natural soils.

摘要

植物和微生物产生的酸性磷酸酶在土壤磷(P)的循环中起着重要作用。对大空间尺度上潜在酸性磷酸酶活性(AP)的空间变异及其驱动因素进行量化,有助于减少我们对土壤磷生物有效性理解的不确定性。我们应用两种机器学习方法(随机森林和反向传播人工网络),通过扩大实验室测量的126个田间样本潜在AP活性的现场观测数据,并使用12个环境驱动因素作为预测变量,来模拟欧洲AP的空间格局。反向传播人工网络(BPN)方法解释了AP变异的58%,高于回归树模型(49%)。此外,BPN能够识别欧洲三条样带上AP的梯度。偏相关分析表明,土壤养分(总氮、总磷和活性有机磷)和气候控制因素(年降水量、年平均温度和温度幅度)是影响AP空间变异的主要因素。年平均温度、降水量和土壤总氮含量较高的地区AP含量也较高。土壤总磷(TP)和有机磷(Po)与欧洲模拟的AP呈非单调相关,表明干旱和湿润地区生物群落对磷的利用策略不同。本研究有助于区分各因素对AP产生的影响,并减少估算土壤磷有效性的不确定性。然而,由于缺乏热带地区AP的代表性测量数据,用欧洲数据训练的BPN模型无法生成可靠的全球AP地图。填补这一数据空白将有助于我们理解天然土壤中磷利用策略的生理基础。

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