miR319/TaGAMYB3 模块调控普通小麦株型结构和提高产量。

The miR319/TaGAMYB3 module regulates plant architecture and improves grain yield in common wheat (Triticum aestivum).

机构信息

Key Laboratory of Crop Gene Resources and Germplasm Enhancement, Institute of Crop Sciences, Chinese Academy of Agricultural Sciences, Beijing, 100081, China.

College of Life Sciences, Northwest A&F University, Yangling, Shaanxi, 712100, China.

出版信息

New Phytol. 2022 Aug;235(4):1515-1530. doi: 10.1111/nph.18216. Epub 2022 May 27.

DOI:10.1111/nph.18216

PMID:35538666

Abstract

Plant architecture is a key determinant of crop productivity and adaptation. The highly conserved microRNA319 (miR319) family functions in various biological processes, but little is known about how miR319 regulates plant architecture in wheat (Triticum aestivum). Here, we determined that the miR319/TaGAMYB3 module controls plant architecture and grain yield in common wheat. Repressing tae-miR319 using short tandem target mimics resulted in favorable plant architecture traits, including increased plant height, reduced tiller number, enlarged spikes and flag leaves, and thicker culms, as well as enhanced grain yield in field plot tests. Overexpressing tae-miR319 had the opposite effects on plant architecture and grain yield. Although both TaPCF8 and TaGAMYB3 were identified as miR319 target genes, genetic complementation assays demonstrated that only miR319-resistant TaGAMYB3 (rTaGAMYB3) abolished tae-miR319-mediated growth inhibition of flag leaves and spikes. TaGAMYB3 functions as a transcriptional activator of downstream genes, including TaPSKR1, TaXTH23, TaMADS5 and TaMADS51, by binding to their promoters. Furthermore, TaGAMYB3 physically interacts with TaBA1, an important regulator of spike development, to additively activate the transcription of downstream genes such as TaMADS5. Our findings provide insight into how the miR319/TaGAMYB3 module regulates plant architecture and improves grain yield in common wheat.

摘要

植物结构是作物生产力和适应性的关键决定因素。高度保守的 microRNA319（miR319）家族在各种生物过程中发挥作用，但对于 miR319 如何调节小麦（Triticum aestivum）的植物结构知之甚少。在这里，我们确定 miR319/TaGAMYB3 模块控制普通小麦的植物结构和籽粒产量。使用短串联靶标模拟物抑制 tae-miR319 可导致有利的植物结构特征，包括增加株高、减少分蘖数、增大穗和旗叶、以及增加茎秆厚度，并在田间试验中提高籽粒产量。过表达 tae-miR319 对植物结构和籽粒产量有相反的影响。虽然 TaPCF8 和 TaGAMYB3 都被鉴定为 miR319 的靶基因，但遗传互补实验表明，只有 miR319 抗性 TaGAMYB3（rTaGAMYB3）消除了 tae-miR319 对旗叶和穗生长的抑制作用。TaGAMYB3 通过结合其启动子作为下游基因，包括 TaPSKR1、TaXTH23、TaMADS5 和 TaMADS51 的转录激活剂发挥作用。此外，TaGAMYB3 与 TaBA1 物理相互作用，TaBA1 是穗发育的重要调节剂，可累加激活下游基因如 TaMADS5 的转录。我们的研究结果提供了对 miR319/TaGAMYB3 模块如何调节普通小麦植物结构和提高籽粒产量的深入了解。

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miR319/TaGAMYB3 模块调控普通小麦株型结构和提高产量。

The miR319/TaGAMYB3 module regulates plant architecture and improves grain yield in common wheat (Triticum aestivum).

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