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Engineered pattern recognition receptors enhance broad-spectrum plant resistance

Yuankun Yang, Christina E. Steidele, Xianlong Huang, Birgit Löffelhardt, Lili Huang, Jonathan D. G. Jones, Thorsten Nürnberger, Pingtao Ding, Andrea A. Gust

2025Nature Biotechnology9 citationsDOIOpen Access PDF

Abstract

Conventional plant resistance breeding has primarily focused on intracellular immune receptors, while cell-surface pattern recognition receptors (PRRs) have been underexplored because of their comparatively modest contributions to resistance. However, PRRs offer untapped potential for crop improvement. Here we demonstrate that the Arabidopsis receptor-like protein RLP23, which recognizes molecular patterns from three distinct microbial kingdoms, confers broad-spectrum resistance when introduced into the Solanaceae crop tomato. We also identify the C-terminal domain of RLPs as crucial for ensuring compatibility and efficacy during heterologous expression. Targeted engineering of the C-terminal domain significantly enhances RLP23 and its use, enabling transfer of robust resistance against bacterial, fungal and oomycete pathogens to tomato plants without compromising yield. We extend this RLP engineering strategy to rice and poplar, highlighting its broad applicability. These findings establish a versatile framework for PRR-based engineering, opening additional avenues for sustainable crop protection.

Topics & Concepts

BiologyPattern recognition receptorOomyceteBiotechnologyHeterologousComputational biologyArabidopsisCropPlant disease resistanceHeterologous expressionGenetically engineeredGenetically modified cropsResistance (ecology)ReceptorGenetically modified organismCell biologyImmune systemDomain (mathematical analysis)Plant sciencePlant-Microbe Interactions and ImmunityPlant Pathogenic Bacteria StudiesLegume Nitrogen Fixing Symbiosis
Engineered pattern recognition receptors enhance broad-spectrum plant resistance | Litcius