When architectural plasticity fails to counter the light competition imposed by planting design: an in silico approach using a functional-structural model of oil palm

IF 2.6 Q1 AGRONOMY in silico Plants Pub Date : 2022-05-26 DOI:10.1093/insilicoplants/diac009
Raphaël P A Perez, Rémi Vezy, L. Brancheriau, F. Boudon, François Grand, Merlin Ramel, Doni Artanto Raharjo, J. Caliman, J. Dauzat
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引用次数: 3

Abstract

Functional-structural plant modelling approaches (FSPM) explore the relationships between the 3D structure and the physiological functioning of plants in relation to environmental conditions. In this study, we present a methodological approach that integrated architectural responses to planting design in an oil palm FSPM, and test the impact of planting design and architectural plasticity on physiological responses such as light interception and carbon assimilation. LiDAR-derived and direct measurements were performed on five planting designs to assess the phenotypic plasticity of architectural traits, and allowed evaluating the variations of the main parameters of an existing 3D plant model. Accordingly, we proposed a neighborhood index (NI) as a simple explanatory variable of architectural plasticity, and used NI-based allometries to simulate architectural variations in 3D virtual plants. Light interception and carbon assimilation were then simulated on virtual plots reproducing the five studied designs. We found that the main traits affected by plant proximity were leaf dimensions, leaf weight, and leaf erectness, whereas other structural traits like the frequency of leaflets along the rachis or biomechanical properties of leaves remained unchanged. Our simulation study highlighted model compliance to reproduce architectural plasticity and illustrated how architectural plasticity improved light interception via leaf area expansion, but how the competition for light imposed by the design can counter-balance this benefit in terms of carbon assimilation at stand scale. We conclude on the importance of planting patterns for plants with low architectural plasticity such as oil palm, and how in silico experiments can help in designing innovative planting patterns.
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当建筑可塑性无法对抗种植设计带来的光线竞争时:使用油棕功能结构模型的计算机方法
植物功能结构建模方法(FSPM)探讨了植物的三维结构和生理功能与环境条件之间的关系。在这项研究中,我们提出了一种方法论方法,将建筑对油棕FSPM种植设计的反应结合起来,并测试了种植设计和建筑可塑性对光拦截和碳同化等生理反应的影响。对五种种植设计进行了激光雷达衍生和直接测量,以评估建筑特征的表型可塑性,并允许评估现有3D植物模型的主要参数的变化。因此,我们提出了一个邻域指数(NI)作为建筑可塑性的简单解释变量,并使用基于NI的异向性来模拟三维虚拟植物中的建筑变化。然后在重现五个研究设计的虚拟地块上模拟光拦截和碳同化。我们发现,受植物接近度影响的主要特征是叶片尺寸、叶片重量和叶片直立度,而其他结构特征,如叶片沿轴的频率或叶片的生物力学特性保持不变。我们的模拟研究强调了模型的顺应性,以再现建筑塑性,并说明了建筑塑性如何通过扩大叶面积来改善截光,但设计施加的对光的竞争如何在林分规模的碳同化方面抵消这一优势。我们总结了种植模式对低建筑可塑性植物(如油棕)的重要性,以及计算机实验如何帮助设计创新的种植模式。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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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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