人工智能揭示了土壤性质和气候因素对栗树不同树龄栗树酵母菌和网纹酵母菌丝体的关键相互作用

IF 2.1 Q3 SOIL SCIENCE Frontiers in soil science Pub Date : 2023-10-06 DOI:10.3389/fsoil.2023.1159793
Serena Santolamazza-Carbone, Laura Iglesias-Bernabé, Mariana Landin, Elena Benito Rueda, M. Esther Barreal, Pedro Pablo Gallego
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引用次数: 0

摘要

本研究主要目的是利用传统统计和人工神经网络工具,确定两个重要的非生物因子(土壤和气候)对外生菌根真菌Boletus edulis和B. reticulatus菌丝浓度和频率的可能相互作用。采用实时荧光定量pcr技术,对3个40岁、10岁和3岁的板栗(Castanea × coudercii)果园中Boletus菌丝体的频率和浓度进行了为期3个月(9月、10月和11月)和2年(2018年和2020年)的测定。统计分析表明,年份对毛竹菌丝体浓度有显著影响,采样样地(不同树龄)对毛竹频率有显著影响。人工智能网络(ANN)与模糊逻辑的结合,称为神经模糊逻辑(NF),允许构建两个鲁棒模型。首先,利用年、月、样地作为输入,NF识别了毛竹菌丝浓度的年、月、样地菌丝频率的月、样地菌丝频率的隐含交互作用,提高了统计分析所得信息的准确性。在第二个模型中,这三个因素被分解为44个输入,包括20个土壤性质和24个气候因素,NF只能选择8个关键因素来解释两种外生菌根Boletus物种在菌丝频率和浓度方面的差异。具体而言,NF选择了土壤的两种化学性质(阳离子交换容量和总碳)和三种物理性质(大团聚体、总孔隙度和土壤水分),以及它们与前两个月降水与潜在蒸散的累积差(P-PET-1-2)和水分亏缺(pd -1-2)以及采样前一个月水分过剩(WE-1)三个气候要素的相互作用。这些结果对板栗农业生态系统中外生菌根真菌(如B. edulis和B. reticulatus)不同菌丝发育模式的生态学和非生物因子的作用有了更深入的认识和新的认识。
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Artificial intelligence unveils key interactions between soil properties and climate factors on Boletus edulis and B. reticulatus mycelium in chestnut orchards of different ages
The main objective of this study was to determine the possible interaction of two important abiotic factors (soil and climate) on the mycelial concentration and frequency of the ectomycorrhizal fungi Boletus edulis and B. reticulatus , using traditional statistics and artificial neural network tools. The frequency and concentration of Boletus mycelium were determined over three months (September, October, and November), and two years (2018 and 2020), in three hybrid chestnuts ( Castanea × coudercii) orchards of 40-, 10-, and 3- years-old, using real-time qPCR. Statistical analysis revealed a significant effect of the year on B. edulis mycelium concentration and of the sampling plot (different tree ages) on B. reticulatus frequency. The combination of artificial intelligence networks (ANN) with fuzzy logic, named neurofuzzy logic (NF), allowed the construction of two robust models. In the first, using year, month, and sampling plot as inputs, NF identified hidden interactions between year and month on B. edulis mycelium concentration and between sampling plot and sampling month on B. reticulatus mycelium frequency, thus improving the information obtained from the statistical analysis. In the second model, those three factors were disaggregated into 44 inputs, including 20 soil properties and 24 climatic factors, being NF able to select only 8 as critical factors to explain the variability found in both ectomycorrhizal Boletus species regarding mycelial frequency and concentration. Specifically, NF selected two chemical soil properties (cation exchange capacity and total carbon) and three physical properties (macroaggregates, total porosity, and soil moisture at field capacity), as well as their interactions with three climatic elements (cumulative difference between precipitation and potential evapotranspiration (P-PET-1-2) and water deficit (WD-1-2) in the previous two months and excess water (WE-1) in the month prior to sampling. These results provide a much deeper understanding and new insights into the ecology and the role of abiotic factors which explain the different mycelial development patterns of ectomycorrhizal fungi such as B. edulis and B. reticulatus in chestnut agroecosystems.
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