<p>Drought poses a substantial threat to world food security<sup><CitationRef CitationID="CR1">1</CitationRef>,<CitationRef CitationID="CR2">2</CitationRef></sup>. Maize (<i>Zea mays</i>) is a major crop for food and forage, and is particularly susceptible to drought during flowering<sup><CitationRef CitationID="CR3">3</CitationRef>,<CitationRef CitationID="CR4">4</CitationRef></sup>. As a monoecious plant species, drought induces asynchronous maturation of male and female inflorescences in maize plants, leading to an increased interval between pollen shedding (anthesis) and silk (elongated stigma and style) exposure (silking)<sup><CitationRef CitationID="CR5">5</CitationRef>,<CitationRef CitationID="CR6">6</CitationRef></sup>. This drought-induced anthesis–silking interval (ASI) fundamentally undermines maize yield stability, but the genetic control of the ASI remains largely unknown. Here we report cloning of a quantitative trait locus, <i>Drought Resistance 9</i> (<i>qDR9</i>), that shortens the drought-increased ASI and enhances the yield stability under drought conditions. The causal gene underlying <i>qDR9</i> encodes a Small Auxin Up RNA (SAUR) protein (ZmSAUR72) that is highly expressed in maize silks but downregulated under drought. ZmSAUR72 inhibits a plasma membrane-localized protein phosphatase, thereby increasing H<sup>+</sup>-ATPase activity and promoting silk growth. The favourable <i>ZmSAUR72</i> allele—which lacks a transposon-like insertion in its promoter—drives higher expression, shortens ASI under drought, stabilizes yield and imposes no yield penalty under normal conditions. Thus, our findings offer new insights into maize ASI under drought and provide strong candidate genes to breed maize cultivars with enhanced yield stability under water-deficit conditions.</p>

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A SAUR gene enhances maize drought resilience by promoting silk elongation

  • Chaohui Zhu,
  • Zhirui Yang,
  • Shiping Yang,
  • Xueyan Zhou,
  • Boxin Liu,
  • Tian Tian,
  • Bochen Zhao,
  • Yingying Xie,
  • Yujun Liu,
  • Jinkui Cheng,
  • Huaijun Tang,
  • Yanjun Zhang,
  • Xiaoqing Xie,
  • Lei Zhang,
  • Cheng Liu,
  • Xingrong Wang,
  • Shengxue Liu,
  • Feng Qin

摘要

Drought poses a substantial threat to world food security1,2. Maize (Zea mays) is a major crop for food and forage, and is particularly susceptible to drought during flowering3,4. As a monoecious plant species, drought induces asynchronous maturation of male and female inflorescences in maize plants, leading to an increased interval between pollen shedding (anthesis) and silk (elongated stigma and style) exposure (silking)5,6. This drought-induced anthesis–silking interval (ASI) fundamentally undermines maize yield stability, but the genetic control of the ASI remains largely unknown. Here we report cloning of a quantitative trait locus, Drought Resistance 9 (qDR9), that shortens the drought-increased ASI and enhances the yield stability under drought conditions. The causal gene underlying qDR9 encodes a Small Auxin Up RNA (SAUR) protein (ZmSAUR72) that is highly expressed in maize silks but downregulated under drought. ZmSAUR72 inhibits a plasma membrane-localized protein phosphatase, thereby increasing H+-ATPase activity and promoting silk growth. The favourable ZmSAUR72 allele—which lacks a transposon-like insertion in its promoter—drives higher expression, shortens ASI under drought, stabilizes yield and imposes no yield penalty under normal conditions. Thus, our findings offer new insights into maize ASI under drought and provide strong candidate genes to breed maize cultivars with enhanced yield stability under water-deficit conditions.