Genomic prediction of cereal crop architecture traits using models informed by gene regulatory circuitries from maize

Edoardo Bertolini, Mohith Manjunath, Weihao Ge, Matthew D. Murphy, Mirai Inaoka, Christina Fliege, Andrea L. Eveland, Alexander E. Lipka
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Abstract

Plant architecture is a major determinant of planting density, which enhances productivity potential for crops per unit area. Genomic prediction is well-positioned to expedite genetic gain of plant architecture traits since they are typically highly heritable. Additionally, the adaptation of genomic prediction models to query predictive abilities of markers tagging certain genomic regions could shed light on the genetic architecture of these traits. Here, we leveraged transcriptional networks from a prior study that contextually described developmental progression during tassel and leaf organogenesis in maize (Z. mays) to inform genomic prediction models for architecture traits. Since these developmental processes underlie tassel branching and leaf angle, two important agronomic architecture traits, we tested whether genes prioritized from these networks quantitatively contribute to the genetic architecture of these traits. We used genomic prediction models to evaluate the ability of markers in the vicinity of prioritized network genes to predict breeding values of tassel branching and leaf angle traits for two diversity panels in maize, and diversity panels from sorghum (S. bicolor) and rice (O. sativa). Predictive abilities of markers near these prioritized network genes were similar to those using whole-genome marker sets. Notably, markers near highly connected transcription factors from core network motifs in maize yielded predictive abilities that were significantly greater than expected by chance in not only maize but also closely related sorghum. We expect that these highly connected regulators are key drivers of architectural variation that are conserved across closely related cereal crop species.
利用玉米基因调控回路模型对谷类作物结构特征进行基因组预测
植物结构是种植密度的主要决定因素,而种植密度可提高作物单位面积的生产潜力。基因组预测非常适合加快植物结构性状的遗传增益,因为这些性状通常具有高度遗传性。此外,调整基因组预测模型以查询标记某些基因组区域的标记物的预测能力,可以揭示这些性状的遗传结构。在这里,我们利用先前一项研究中的转录网络(该研究结合上下文描述了玉米(Z. mays)穗和叶器官发生过程中的发育进程)来为结构性状的基因组预测模型提供信息。由于这些发育过程是穗分枝和叶片角度这两个重要农艺结构性状的基础,我们测试了从这些网络中优先排序的基因是否对这些性状的遗传结构有定量贡献。我们使用基因组预测模型评估了优先网络基因附近的标记预测玉米两个多样性面板以及高粱(S. bicolor)和水稻(O. sativa)多样性面板的抽穗分枝和叶片角度性状育种价值的能力。这些优先网络基因附近标记的预测能力与使用全基因组标记集的预测能力相似。值得注意的是,在玉米和密切相关的高粱中,玉米核心网络基序中高度连接的转录因子附近标记的预测能力明显高于偶然的预期。我们预计,这些高度连接的调控因子是结构变异的关键驱动因素,它们在近缘谷类作物物种中是保守的。
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