Interactions between nitrogen nutrition, canopy architecture and photosynthesis in rice, assessed using high-resolution 3D reconstruction

IF 2.6 Q1 AGRONOMY in silico Plants Pub Date : 2020-12-30 DOI:10.1093/insilicoplants/diaa017
A. Burgess, Tiara Herman, Asgar Ali, E. Murchie
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引用次数: 1

Abstract

Increasing nitrogen use efficiency is a key target for yield improvement programs. Here we identify features of rice canopy architecture during altered N availability and link them to photosynthetic productivity. Empirical mathematical modelling, high-resolution 3-dimensional (3D) reconstruction and gas exchange measurements were employed to investigate the effect of a mild N deficiency vs. surplus N application on canopy architecture, light and photosynthesis distribution throughout development. Three contrasting rice lines: two Malaysian rice varieties (MR219 and MR253) and a high-yielding indica cultivar (IR64) were cultivated. 3D reconstruction indicated key N-dependent differences in plant architecture and canopy light distribution including changes to leaf area index (LAI), tiller number, leaf angle and modelled light extinction coefficients. Measured leaf photosynthetic capacity did not differ substantially between the high and reduced N treatments; however, modelled canopy photosynthesis rate indicated a higher carbon gain per unit leaf area for the reduced N treatment but a higher carbon gain per unit ground area for the high N treatment. This is a result of altered canopy structure leading to increased light distribution under reduced N which partially offsets the reduced LAI. Within rice, altered N availability results in the development of full photosynthetically functional leaves, but leads to altered canopy architecture, light distribution and overall productivity suggested that N availability can be fine-tuned to optimize biomass production. We propose wider use of 3D reconstruction to assess canopy architecture and productivity under differing N availabilities for a range of species.
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利用高分辨率3D重建评估水稻氮营养、冠层结构和光合作用之间的相互作用
提高氮素利用效率是提高产量计划的关键目标。在这里,我们确定了氮有效性改变期间水稻冠层结构的特征,并将它们与光合生产力联系起来。利用经验数学模型、高分辨率三维(3D)重建和气体交换测量,研究了轻度缺氮和过量施氮对整个发育过程中冠层结构、光照和光合作用分布的影响。三个对比水稻品系:两个马来西亚水稻品种(MR219和MR253)和一个高产籼稻品种(IR64)。三维重建显示了植物构型和冠层光分布的关键氮依赖差异,包括叶面积指数(LAI)、分蘖数、叶片角度和模拟光消系数的变化。测定的叶片光合能力在高氮处理和低氮处理之间没有显著差异;然而,模拟的冠层光合速率表明,低氮处理的单位叶面积碳增益更高,而高氮处理的单位地面面积碳增益更高。这是由于冠层结构的改变导致N降低时光分布增加,这部分抵消了LAI的减少。在水稻中,氮素有效性的改变导致光合功能叶片的发育,但导致冠层结构、光分布和整体生产力的改变,这表明氮素有效性可以微调以优化生物量生产。我们建议更广泛地使用三维重建来评估不同氮有效度下不同物种的冠层结构和生产力。
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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
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