Genetic mapping of dynamic control of leaf angle across multiple canopy levels in maize

Matthew J. Dzievit, Xianran Li, Jianming Yu
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Abstract

Optimizing leaf angle and other canopy architecture traits has helped modern maize (Zea mays L.) become adapted to higher planting densities over the last 60 years. Traditional investigations into genetic control of leaf angle have focused on one leaf or the average of multiple leaves; as a result, our understanding of genetic control across multiple canopy levels is still limited. To address this, genetic mapping across four canopy levels was conducted in the present study to investigate the genetic control of leaf angle across the canopy. We developed two populations of doubled haploid lines derived from three inbreds with distinct leaf angle phenotypes. These populations were genotyped with genotyping-by-sequencing and phenotyped for leaf angle at four different canopy levels over multiple years. To understand how leaf angle changes across the canopy, the four measurements were used to derive three additional traits. Composite interval mapping was conducted with the leaf-specific measurements and the derived traits. A set of 59 quantitative trait loci (QTLs) were uncovered for seven traits, and two genomic regions were consistently detected across multiple canopy levels. Additionally, seven genomic regions were found to contain consistent QTLs with either relatively stable or dynamic effects at different canopy levels. Prioritizing the selection of QTLs with dynamic effects across the canopy will aid breeders in selecting maize hybrids with the ideal canopy architecture that continues to maximize yield on a per area basis under increasing planting densities.
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玉米多冠层叶片角度动态控制的遗传图谱
优化叶片角度和其他冠层结构性状有助于现代玉米(Zea mays L.)在过去 60 年中适应更高的种植密度。对叶片角度遗传控制的传统研究主要集中在一片叶片或多片叶片的平均值上;因此,我们对多层冠层遗传控制的了解仍然有限。为了解决这个问题,本研究进行了跨越四个树冠层的遗传图谱绘制,以研究整个树冠层的叶片角度遗传控制。我们从三个具有不同叶角表型的近交系中培育出了两个加倍单倍体品系群体。通过基因分型测序对这些群体进行了基因分型,并在多年中对四个不同冠层的叶角进行了表型分析。为了了解叶片角度在整个冠层中的变化情况,还利用这四种测量方法得出了另外三个性状。利用叶片特异性测量和衍生性状进行了复合区间作图。为七个性状发现了一组 59 个数量性状位点(QTL),并在多个冠层中持续检测到两个基因组区域。此外,还发现七个基因组区域包含一致的 QTLs,在不同冠层中具有相对稳定或动态的效应。优先选择冠层中具有动态效应的 QTLs 将有助于育种者选择具有理想冠层结构的玉米杂交种,从而在种植密度不断增加的情况下继续最大限度地提高单位面积产量。
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