<p>Broad-spectrum resistance genes are highly valuable for sustainable crop protection, yet the molecular basis of their activity is often unknown. The <i>Pm3</i> allelic series in wheat encodes NLR receptors that recognize avirulence (AVR) effectors of wheat powdery mildew. Here, we show that near-identical <i>Pm3</i> alleles vary greatly in resistance efficacy and broadness against a global mildew isolate collection and subsequently use this model system to study the mechanisms underlying broad-spectrum resistance. We demonstrate that two alleles, <i>Pm3d</i> and <i>Pm3e</i>, provide resistance against most isolates worldwide, by each recognizing two <i>AVR</i> genes, thereby lowering the risk of resistance breakdown. Pm3d recognizes two highly similar RNase-like AVRs, encoded by gene paralogs. In contrast, Pm3e detects two structurally diverse AVRs: one shared with Pm3d, the other originating from a large, uncharacterized protein family with a discrete structural fold.&#xa0;Using chimeric Pm3 NLRs, we identify specificity-defining polymorphisms of Pm3d and Pm3e against their diverse effector targets. Lastly, we demonstrate that Pm3d and Pm3e activities can be combined in engineered Pm3 NLRs, thereby further extending their recognition spectrum. Our findings highlight the potential of Pm3 immune receptors for long-lasting wheat protection by demonstrating their versatility in recognizing structurally diverse effectors and their amenability to NLR engineering.</p>

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Dual recognition of structurally unrelated mildew effectors underlies the broad-spectrum resistance of Pm3e in wheat

  • Lukas Kunz,
  • Zoe Bernasconi,
  • Matthias Heuberger,
  • Jonatan Isaksson,
  • Alexandros G. Sotiropoulos,
  • Ursin Stirnemann,
  • Jigisha Jigisha,
  • Fabrizio Menardo,
  • Thomas Wicker,
  • Marion C. Müller,
  • Beat Keller

摘要

Broad-spectrum resistance genes are highly valuable for sustainable crop protection, yet the molecular basis of their activity is often unknown. The Pm3 allelic series in wheat encodes NLR receptors that recognize avirulence (AVR) effectors of wheat powdery mildew. Here, we show that near-identical Pm3 alleles vary greatly in resistance efficacy and broadness against a global mildew isolate collection and subsequently use this model system to study the mechanisms underlying broad-spectrum resistance. We demonstrate that two alleles, Pm3d and Pm3e, provide resistance against most isolates worldwide, by each recognizing two AVR genes, thereby lowering the risk of resistance breakdown. Pm3d recognizes two highly similar RNase-like AVRs, encoded by gene paralogs. In contrast, Pm3e detects two structurally diverse AVRs: one shared with Pm3d, the other originating from a large, uncharacterized protein family with a discrete structural fold. Using chimeric Pm3 NLRs, we identify specificity-defining polymorphisms of Pm3d and Pm3e against their diverse effector targets. Lastly, we demonstrate that Pm3d and Pm3e activities can be combined in engineered Pm3 NLRs, thereby further extending their recognition spectrum. Our findings highlight the potential of Pm3 immune receptors for long-lasting wheat protection by demonstrating their versatility in recognizing structurally diverse effectors and their amenability to NLR engineering.