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The synthetic NLR RGA5HMA5 requires multiple interfaces within and outside the integrated domain for effector recognition

Xin Zhang, Yang Liu, Guixin Yuan, Shiwei Wang, Dongli Wang, Tongtong Zhu, Xue-Feng Wu, Mengqi Ma, Liwei Guo, Hailong Guo, Vijai Bhadauria, Junfeng Liu, You‐Liang Peng

2024Nature Communications30 citationsDOIOpen Access PDF

Abstract

Abstract Some plant sensor nucleotide-binding leucine-rich repeat (NLR) receptors detect pathogen effectors through their integrated domains (IDs). Rice RGA5 sensor NLR recognizes its corresponding effectors AVR-Pia and AVR1-CO39 from the blast fungus Magnaporthe oryzae through direct binding to its heavy metal-associated (HMA) ID to trigger the RGA4 helper NLR-dependent resistance in rice. Here, we report a mutant of RGA5 named RGA5 HMA5 that confers complete resistance in transgenic rice plants to the M. oryzae strains expressing the noncorresponding effector AVR-PikD. RGA5 HMA5 carries three engineered interfaces, two of which lie in the HMA ID and the other in the C-terminal Lys-rich stretch tailing the ID. However, RGA5 variants having one or two of the three interfaces, including replacing all the Lys residues with Glu residues in the Lys-rich stretch, failed to activate RGA4-dependent cell death of rice protoplasts. Altogether, this work demonstrates that sensor NLRs require a concerted action of multiple surfaces within and outside the IDs to both recognize effectors and activate helper NLR-mediated resistance, and has implications in structure-guided designing of sensor NLRs.

Topics & Concepts

EffectorGenetically modified riceMutantBiologyCell biologyComputational biologyPathogenGeneMagnaportheTransgeneGeneticsOryza sativaMagnaporthe griseaGenetically modified cropsPlant-Microbe Interactions and ImmunityPlant tissue culture and regenerationFungal and yeast genetics research
The synthetic NLR RGA5HMA5 requires multiple interfaces within and outside the integrated domain for effector recognition | Litcius