College of Life Sciences, Northwest A&F University, Yangling, 712100, China.
State Key Laboratory of Crop Gene Resources and Breeding, Institute of Crop Sciences, Chinese Academy of Agricultural Sciences, Beijing, 100081, China.
J Integr Plant Biol. 2024 Nov;66(11):2362-2378. doi: 10.1111/jipb.13759. Epub 2024 Aug 7.
Wheat culms, comprising four to six internodes, are critically involved in determining plant height and lodging resistance, essential factors for field performance and regional adaptability. This study revealed the regulatory function of miR319 in common wheat plant height. Repression of tae-miR319 through short tandem target mimics (STTM) caused an increased plant height, while overexpression (OE) of tae-miR319 had the opposite effect. Overexpressing a miR319-resistant target gene TaPCF8 (rTaPCF8), increased plant height. TaPCF8 acted as a transcription repressor of downstream genes TaIAAs, which interact physically with TaSPL14. The significant differences of indole-3-acetic acid (IAA) contents indicate the involvement of auxin pathway in miR319-mediated plant height regulation. Finally, we identified two TaPCF8 haplotypes in global wheat collections. TaPCF8-5A-Hap2, as per association and evolution examinations, was subjected to strong substantial selection throughout wheat breeding. This haplotype, associated with shorter plant height, aligns with global breeding requirements. Consequently, in high-yield wheat breeding, we proposed a potential molecular marker for marker-assisted selection (MAS). Our findings offer fresh perspectives into the molecular mechanisms that underlie the miR319-TaPCF8 module's regulation of plant height by orchestrating auxin signaling and biosynthesis in wheat.
小麦茎秆由四到六个节间组成,对株高和抗倒伏性起着关键作用,这是田间表现和区域适应性的重要因素。本研究揭示了 miR319 在普通小麦株高中的调控功能。通过短串联靶标模拟物(STTM)抑制 tae-miR319 导致株高增加,而过表达 tae-miR319 则产生相反的效果。过表达 miR319 抗性靶基因 TaPCF8(rTaPCF8)会增加株高。TaPCF8 作为下游基因 TaIAAs 的转录抑制子,与 TaSPL14 物理相互作用。生长素(IAA)含量的显著差异表明生长素途径参与了 miR319 介导的株高调控。最后,我们在全球小麦群体中鉴定出两种 TaPCF8 单倍型。通过关联和进化研究发现,TaPCF8-5A-Hap2 在小麦育种过程中受到强烈的实质性选择。这种与较短株高相关的单倍型与全球育种要求一致。因此,在高产小麦育种中,我们提出了一个潜在的分子标记,用于辅助选择(MAS)。我们的研究结果为 miR319-TaPCF8 模块通过协调生长素信号转导和生物合成来调控小麦株高的分子机制提供了新的视角。
