Integration of crop growth model and constraint-based metabolic model predicts metabolic changes over rice plant development under water-limited stress

IF 2.6 Q1 AGRONOMY

in silico Plants Pub Date : 2021-07-01 DOI:10.1093/INSILICOPLANTS/DIAB020

R. Shaw, C. Y. M. Cheung

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引用次数: 3

Abstract

Rice is a major staple food worldwide and understanding its metabolism is essential for improving crop yield and quality, especially in a changing climate. Constraint-based modelling is an established method for studying metabolism at a systems level, but one of its limitations is the difficulty in directly integrating certain environmental factors, such as water potential, to the model for predicting metabolic changes in response to environmental changes. Here, we developed a framework to integrate a crop growth model and an upgraded diel multi-organ genome-scale metabolic model of rice to predict the metabolism of rice growth under normal and water-limited conditions. Our model was able to predict distinct metabolic adaptations under water-limited stress compared to normal condition across multiple developmental stages. Our modelling results of dynamic changes in metabolism over the whole-plant growth period highlighted key features of rice metabolism under water-limited stress including early leaf senescence, reduction in photosynthesis and significant nitrogen assimilation during grain filling.

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结合作物生长模型和基于约束的代谢模型预测水分限制胁迫下水稻植株发育过程中的代谢变化

水稻是全世界的主要主食，了解其代谢对于提高作物产量和质量至关重要，尤其是在气候变化的情况下。基于约束的建模是一种在系统层面研究代谢的既定方法，但其局限性之一是难以将某些环境因素（如水势）直接集成到预测响应环境变化的代谢变化的模型中。在这里，我们开发了一个框架，将作物生长模型和升级的水稻diel多器官基因组规模代谢模型相结合，以预测正常和水分限制条件下水稻生长的代谢。与正常条件相比，我们的模型能够预测在多个发育阶段在水分限制应激下的不同代谢适应。我们对整个植物生长期代谢动态变化的建模结果突出了水分限制胁迫下水稻代谢的关键特征，包括叶片早衰、光合作用减少和灌浆期间氮同化显著。

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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