On the pivotal role of water potential to model plant physiological processes

IF 2.6 Q1 AGRONOMY in silico Plants Pub Date : 2022-01-18 DOI:10.1093/insilicoplants/diab038
T. De Swaef, Olivier Pieters, S. Appeltans, I. Borra‐Serrano, Willem Coudron, V. Couvreur, S. Garré, P. Lootens, B. Nicolaï, L. Pols, Clément Saint Cast, J. Šalagovič, Maxime Van Haeverbeke, Michiel Stock, F. Wyffels
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引用次数: 11

Abstract

Water potential explains water transport in the Soil-Plant-Atmosphere Continuum (SPAC), and is gaining interest as connecting variable between ‘pedo-, bio- and atmosphere’. It is primarily used to simulate hydraulics in the SPAC, and is thus essential for studying drought effects. Recent implementations of hydraulics in large-scale Terrestrial Biosphere Models (TBMs) improved their performance under water-limited conditions, while hydraulic features of recent detailed Functional-Structural Plant Models (FSPMs) open new possibilities for dissecting complex traits for drought tolerance. These developments in models across scales deserve a critical appraisal to evaluate its potential for wider use in FSPMs, but also in crop systems models (CSMs), where hydraulics are currently still absent. After refreshing the physical basis, we first address models where water potential is primarily used for describing water transport along the transpiration pathway from the soil to the leaves, through the roots, the xylem and the leaf mesophyll. Then, we highlight models for three ecophysiological processes, which have well-recognised links to water potential: phloem transport, stomatal conductance and organ growth. We identify water potential as the bridge between soil, root and shoot models, as the physiological variable integrating below- and above-ground abiotic drivers, but also as the link between water status and growth. Models making these connections enable identifying crucial traits for ecosystem resilience to drought and for breeding towards improved drought tolerance in crops. Including hydraulics often increases model complexity, and thus requires experimental data on soil and plant hydraulics. Nevertheless, modelling hydraulics is insightful at different scales (FSPMs, CSMs and TBMs).
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论水势在模拟植物生理过程中的关键作用
水势解释了土壤-植物-大气连续体(SPAC)中的水分输送,并作为“土壤、生物和大气”之间的连接变量而越来越受到关注。它主要用于模拟SPAC中的水力学,因此对于研究干旱影响至关重要。最近在大规模陆地生物圈模型(tbm)中的水力学实现提高了它们在水限制条件下的性能,而最近详细的功能结构植物模型(FSPMs)的水力特征为解剖复杂的耐旱性性状开辟了新的可能性。这些跨尺度模型的发展值得进行批判性评估,以评估其在FSPMs中更广泛应用的潜力,以及在作物系统模型(csm)中,液压技术目前仍然缺席。在更新了物理基础之后,我们首先讨论水势模型,其中水势主要用于描述水分沿着蒸腾途径从土壤到叶片,通过根、木质部和叶肉的运输。然后,我们强调了三个生态生理过程的模型,它们与水势有很好的联系:韧皮部运输,气孔导度和器官生长。我们认为水势是土壤、根和茎模型之间的桥梁,是整合地上和地下非生物驱动因素的生理变量,也是水分状况与生长之间的联系。建立这些联系的模型能够确定生态系统抗旱能力的关键特征,并有助于提高作物的耐旱性。包括水力学通常会增加模型的复杂性,因此需要土壤和植物水力学的实验数据。尽管如此,在不同的尺度(fspm, csm和tbm)上建模水力学是有见地的。
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来源期刊
in silico Plants
in silico Plants Agricultural and Biological Sciences-Agronomy and Crop Science
CiteScore
4.70
自引率
9.70%
发文量
21
审稿时长
10 weeks
期刊最新文献
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