Dongxue Zhao, Peter de Voil, Victor O. Sadras, Jairo A. Palta, Daniel Rodriguez
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引用次数: 0
摘要
表型可塑性是应对环境异质性的一种有价值的适应策略。关于根系性状的可塑性及其对产量和产量稳定性的影响的资料有限。目的从表型可塑性的角度出发,重点研究大田栽培高粱根系功能性状与水分吸收的关系,以回答:(i)遗传(G)、环境(E)和管理(M)因素及其相互作用如何影响根系性状?根系性状及其可塑性如何影响产量和产量稳定性?方法在G × E × M试验中,采用一种新的高通量功能性根系表型分析方法,对最大生根深度(MxRD)和根系活性指数(RAindex)两个根系性状进行定量分析。采用反应范数法测定作物表型可塑性。结果G × E × M处理在杂交组合间产生了塑性响应。所研究的不同性状(粒数性状、根系性状、粒重性状)具有一定的可塑性等级。根系性状的可塑性与籽粒产量性状的稳定性有关。根系可塑性高的杂交种籽粒数和粒重趋于稳定。结论根性状的平均值和可塑性具有重要的遗传多样性,可用于根表型与目标生产环境的匹配。我们的根系表型分析方法可以为了解不同环境下田间根系功能、根系结构和产量性状之间的动态相互作用提供有价值的工具。
The plasticity of root traits and their effects on crop yield and yield stability
Context
Phenotypic plasticity can be a valuable adaptation strategy for coping with environmental heterogeneity. There is limited information on the plasticity of root traits and their effect on yield and yield stability.
Objectives
With a perspective of phenotypic plasticity, we focus on functional root traits associated to water uptake in field-grown sorghum to answer: (i) How do genetic (G), environmental (E) and management (M) factors and their interactions, affect the root traits? and (ii) How do root traits and their plasticity affect yield and yield stability?
Methods
A new high-throughput functional root phenotyping approach was used in G × E × M trials to quantify two root traits, maximum rooting depth (MxRD) and a root activity index (RAindex). Crop phenotypic plasticities were determined using the reaction norm method.
Results
The applied G × E × M treatments created plastic responses between the tested hybrids. There was a hierarchy of plasticities for the different traits studied i.e., grain number traits > root traits > grain weight traits. The plasticity of root traits was associated with the stability of grain yield traits. Hybrids with high root plasticity tend to have more stable grain numbers and grain weights.
Conclusions
There is valuable genetic diversity in the mean value and plasticity of root traits that could be used to match root phenotypes to target production environments. Our root phenotyping approach can be a valuable tool for understanding the dynamic interactions between root function, root architecture and yield traits in the field under variable environments.
期刊介绍:
Plant and Soil publishes original papers and review articles exploring the interface of plant biology and soil sciences, and that enhance our mechanistic understanding of plant-soil interactions. We focus on the interface of plant biology and soil sciences, and seek those manuscripts with a strong mechanistic component which develop and test hypotheses aimed at understanding underlying mechanisms of plant-soil interactions. Manuscripts can include both fundamental and applied aspects of mineral nutrition, plant water relations, symbiotic and pathogenic plant-microbe interactions, root anatomy and morphology, soil biology, ecology, agrochemistry and agrophysics, as long as they are hypothesis-driven and enhance our mechanistic understanding. Articles including a major molecular or modelling component also fall within the scope of the journal. All contributions appear in the English language, with consistent spelling, using either American or British English.
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