Michele Faralli, Greg Mellers, Shellie Wall, Silvere Vialet-Chabrand, Guillaume Forget, Alexander Galle, Jeron Van Rie, Keith A Gardner, Eric S Ober, James Cockram, Tracy Lawson
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引用次数: 0
Abstract
Recent research has shown that optimizing photosynthetic and stomatal traits holds promise for improved crop performance. However, standard phenotyping tools such as gas exchange systems have limited throughput. In this work, a novel approach based on a bespoke gas exchange chamber allowing combined measurement of the quantum yield of PSII (Fq'/Fm'), with an estimation of stomatal conductance via thermal imaging was used to phenotype a range of bread wheat (Triticum aestivum L.) genotypes. Using the dual-imaging methods and traditional approaches, we found broad and significant variation in key traits, including photosynthetic CO2 uptake at saturating light and ambient CO2 concentration (Asat), photosynthetic CO2 uptake at saturating light and elevated CO2 concentration (Amax), the maximum velocity of Rubisco for carboxylation (Vcmax), time for stomatal opening (Ki), and leaf evaporative cooling. Anatomical analysis revealed significant variation in flag leaf adaxial stomatal density. Associations between traits highlighted significant relationships between leaf evaporative cooling, leaf stomatal conductance, and Fq'/Fm', highlighting the importance of stomatal conductance and stomatal rapidity in maintaining optimal leaf temperature for photosynthesis in wheat. Additionally, gsmin and gsmax were positively associated, indicating that potential combinations of preferable traits (i.e. inherently high gsmax, low Ki, and maintained leaf evaporative cooling) are present in wheat. This work highlights the effectiveness of thermal imaging in screening dynamic gs in a panel of wheat genotypes. The wide phenotypic variation observed suggested the presence of exploitable genetic variability in bread wheat for dynamic stomatal conductance traits and photosynthetic capacity for targeted optimization within future breeding programmes.
更好地了解动态环境条件下的作物表型,将有助于开发出能更好地适应不断变化的田间条件的新品种。最近的研究表明,优化光合作用和气孔导度性状有望提高作物性能。然而,标准的表型工具(如气体交换系统)因其吞吐量而受到限制。在这项工作中,采用了一种基于定制气体交换室的新方法,通过热成像技术结合测量光系统 II(PSII)的量子产率和估算气孔导度,对一系列面包小麦(Triticum aestivum L.)基因型进行了表型,这些基因型是多创始人实验群体的子集。通过测量光合能力和气孔密度进一步补充了数据集。首先,我们发现,使用我们的双成像系统测量气孔性状与标准 IRGA 方法相比,在气孔开放速度(Ki)方面,两种方法具有良好的一致性(R2=0.86),双成像方法导致基因型内差异较小。利用双成像方法和传统方法,我们发现关键性状存在广泛而显著的差异,包括饱和光照和环境 CO2 浓度下的光合 CO2 摄取量(Asat)、饱和光照和 CO2 浓度升高时的光合 CO2 摄取量(Amax)、Rubisco 羧化的最大速度(Vcmax)、气孔开放时间(Ki)和叶片蒸发冷却。解剖分析表明,旗叶正面气孔密度存在显著差异。性状之间的关联突显了叶片蒸发冷却、低光照强度(gsmin)和高光照强度(gsmax)下的叶片气孔导度以及 PSII 的运行效率(Fq'/Fm')之间的显著关系,突出了气孔导度和气孔快速性在维持小麦光合作用的最佳叶片温度方面的重要性。此外,gsmin 和 gsmax 呈正相关,表明小麦中存在潜在的优良性状组合(即固有的高 gsmax、低 Ki 和维持叶片蒸发冷却)。这项研究首次强调了热成像技术在筛选大量小麦基因型的动态气孔导度方面的有效性。观察到的广泛表型变异表明,面包小麦的动态气孔导度性状和光合能力存在可利用的遗传变异,可在未来的育种计划中进行有针对性的优化。
期刊介绍:
The Journal of Experimental Botany publishes high-quality primary research and review papers in the plant sciences. These papers cover a range of disciplines from molecular and cellular physiology and biochemistry through whole plant physiology to community physiology.
Full-length primary papers should contribute to our understanding of how plants develop and function, and should provide new insights into biological processes. The journal will not publish purely descriptive papers or papers that report a well-known process in a species in which the process has not been identified previously. Articles should be concise and generally limited to 10 printed pages.