<p>Rice is a staple crop for more than half of the world’s population, and its sustainable production is vital to ensure global food security. However, rice is susceptible to several devastating fungal diseases<sup><CitationRef CitationID="CR1">1</CitationRef></sup>, including blast disease caused by <i>Magnaporthe oryzae</i>, sheath blight by <i>Rhizoctonia solani</i>, false smut by <i>Ustilaginoidea virens</i>, brown spot by <i>Bipolaris oryzae</i>, bakanae by <i>Fusarium fujikuroi</i> and head blight by <i>Fusarium graminearum</i>. The mechanisms underlying the susceptibility to these fungal diseases remain unclear. Here we report that the β subunit of SnRK1, SnRK1β1A, confers broad-spectrum susceptibility to these fungal diseases. Our findings show that diverse rice fungal pathogens have convergently evolved an effector-like protein, Gas2, which interacts with SnRK1β1A to prevent its ubiquitination-mediated degradation and promotes its nuclear translocation. <i>SnRK1β1A</i> is markedly induced on fungal infection, promoting susceptibility by inhibiting SnRK1α1, an α subunit of SnRK1 known to positively regulate broad-spectrum resistance in rice<sup><CitationRef CitationID="CR2">2</CitationRef></sup>. Notably, rice lines with disrupted <i>SnRK1β1A</i> are resistant to several fungal diseases without compromising growth and yield in the field under normal farming conditions. This study demonstrates that broad-spectrum disease resistance in crops can be achieved by disrupting inducible susceptibility genes whose encoded proteins are targeted by effectors conserved across several pathogens.</p>

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Inactivating SnRK1β1A promotes broad-spectrum disease resistance in rice

  • Guixin Yuan,
  • Xunli Lu,
  • Xingbin Wang,
  • Mengfei Li,
  • Shiwei Wang,
  • Zhaoxiang Huang,
  • Zhigang Li,
  • Fengrui Zhang,
  • Xin Zhang,
  • Jun Yang,
  • Hailong Guo,
  • Vijai Bhadauria,
  • Wang-Sheng Zhu,
  • Wensheng Zhao,
  • Meng Yuan,
  • Jian-Min Zhou,
  • You-Liang Peng

摘要

Rice is a staple crop for more than half of the world’s population, and its sustainable production is vital to ensure global food security. However, rice is susceptible to several devastating fungal diseases1, including blast disease caused by Magnaporthe oryzae, sheath blight by Rhizoctonia solani, false smut by Ustilaginoidea virens, brown spot by Bipolaris oryzae, bakanae by Fusarium fujikuroi and head blight by Fusarium graminearum. The mechanisms underlying the susceptibility to these fungal diseases remain unclear. Here we report that the β subunit of SnRK1, SnRK1β1A, confers broad-spectrum susceptibility to these fungal diseases. Our findings show that diverse rice fungal pathogens have convergently evolved an effector-like protein, Gas2, which interacts with SnRK1β1A to prevent its ubiquitination-mediated degradation and promotes its nuclear translocation. SnRK1β1A is markedly induced on fungal infection, promoting susceptibility by inhibiting SnRK1α1, an α subunit of SnRK1 known to positively regulate broad-spectrum resistance in rice2. Notably, rice lines with disrupted SnRK1β1A are resistant to several fungal diseases without compromising growth and yield in the field under normal farming conditions. This study demonstrates that broad-spectrum disease resistance in crops can be achieved by disrupting inducible susceptibility genes whose encoded proteins are targeted by effectors conserved across several pathogens.