不同水分供应条件下的四季豆揭示了植物电色素中可分类的刺激特异性特征。

Plant signaling & behavior Pub Date : 2024-12-31 Epub Date: 2024-03-28 DOI:10.1080/15592324.2024.2333144
Gabriel R A de Toledo, Gabriela N Reissig, Luiz G S Senko, Danillo R Pereira, Arlan F da Silva, Gustavo M Souza
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引用次数: 0

摘要

植物电生理学揭示了电信号对植物生理和行为的影响。自发产生的生物电活动会随着环境条件的变化而改变,这表明植物的电子信号可能具有与各种刺激相关的独特特征。结合机器学习(ML)技术分析电信号,特别是电子电信号,已成为一种很有前途的方法,可对与各种刺激相对应的特征电信号进行分类。本研究旨在描述蚕豆(Phaseolus vulgaris L.)变种 BRS-Expedito 的电子信号特征。BRS-Expedito)变种的特征,寻找与这些刺激相关的模式。为此,对处于无性生长阶段的豆科植物进行了以下处理:(I)蒸馏水;(II)半强度霍格兰营养液;(III)-2 兆帕 PEG 溶液;(IV)-2 兆帕 NaCl 溶液。在法拉第笼中使用 MP36 电子系统采集数据,记录电信号。同时,通过监测叶片张力的变化来评估植物的水分状况。此外,还测量了叶片温度。对电时间序列数据进行了各种分析,包括电压变化的算术平均值、偏斜度、峰度、概率密度函数(PDF)、自相关性、功率谱密度(PSD)、近似熵(ApEn)、快速傅立叶变换(FFT)和多尺度近似熵(ApEn(s))。对叶片温度、电压变化、偏斜度、峰度、PDF µ 指数、自相关性、PSD β 指数和近似熵数据进行了统计分析。应用机器学习分析方法识别了电气时间序列中的可分类模式。对 BRS-Expedito 蚕豆电图的分析表明,即使水分供应刺激的改变在质量和强度方面相似,电图也是受刺激影响的。此外,研究还发现,豆类电图表现出很高的复杂性,不同的刺激会改变其复杂性,更强烈和厌恶性的刺激会导致复杂性急剧下降。值得注意的是,其中一项重要发现是小型向量机利用电图数据检测盐胁迫的准确率达到了 100%。此外,该研究还强调了植物在低水势条件下,在叶片张力发生可观察到的变化之前,植物电图发生的变化。这项研究表明,电图有可能被用作豆科植物水分状况的生理指标。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Common bean under different water availability reveals classifiable stimuli-specific signatures in plant electrome.

Plant electrophysiology has unveiled the involvement of electrical signals in the physiology and behavior of plants. Spontaneously generated bioelectric activity can be altered in response to changes in environmental conditions, suggesting that a plant's electrome may possess a distinct signature associated with various stimuli. Analyzing electrical signals, particularly the electrome, in conjunction with Machine Learning (ML) techniques has emerged as a promising approach to classify characteristic electrical signals corresponding to each stimulus. This study aimed to characterize the electrome of common bean (Phaseolus vulgaris L.) cv. BRS-Expedito, subjected to different water availabilities, seeking patterns linked to these stimuli. For this purpose, bean plants in the vegetative stage were subjected to the following treatments: (I) distilled water; (II) half-strength Hoagland's nutrient solution; (III) -2 MPa PEG solution; and (IV) -2 MPa NaCl solution. Electrical signals were recorded within a Faraday's cage using the MP36 electronic system for data acquisition. Concurrently, plant water status was assessed by monitoring leaf turgor variation. Leaf temperature was additionally measured. Various analyses were conducted on the electrical time series data, including arithmetic average of voltage variation, skewness, kurtosis, Probability Density Function (PDF), autocorrelation, Power Spectral Density (PSD), Approximate Entropy (ApEn), Fast Fourier Transform (FFT), and Multiscale Approximate Entropy (ApEn(s)). Statistical analyses were performed on leaf temperature, voltage variation, skewness, kurtosis, PDF µ exponent, autocorrelation, PSD β exponent, and approximate entropy data. Machine Learning analyses were applied to identify classifiable patterns in the electrical time series. Characterization of the electrome of BRS-Expedito beans revealed stimulus-dependent profiles, even when alterations in water availability stimuli were similar in terms of quality and intensity. Additionally, it was observed that the bean electrome exhibits high levels of complexity, which are altered by different stimuli, with more intense and aversive stimuli leading to drastic reductions in complexity levels. Notably, one of the significant findings was the 100% accuracy of Small Vector Machine in detecting salt stress using electrome data. Furthermore, the study highlighted alterations in the plant electrome under low water potential before observable leaf turgor changes. This work demonstrates the potential use of the electrome as a physiological indicator of the water status in bean plants.

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