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SALICYLIC ACID SENSOR1 reveals the propagation of an SA hormone surge during plant pathogen advance

Bijun Tang, Jing Lü, Hana Leontovyčová, Gesa Hoffmann, James Rowe, Sacha Fouquay O’Donnell, Mathieu Grangé-Guermente, Bo Larsen, Rinukshi Wimalasekera, Philip Carella, Marco Incarbone, Tetiana Kalachova, Alexander M. Jones

2025Science8 citationsDOIOpen Access PDF

Abstract

bacteria. The timing and extent of SA accumulation are tightly controlled by plants but can be suppressed by pathogens to overcome immunity. Understanding SA dynamics at high spatiotemporal resolution remains challenging owing to limitations in existing detection methods that are indirect, destructive, or lacking in cellular precision and temporal resolution. We developed SalicS1, a genetically encoded fluorescence resonance energy transfer (FRET) biosensor specific to SA. SalicS1 enables real-time, reversible monitoring of SA levels in vivo with minimal perturbation of endogenous signaling. We reveal the propagation of an SA surge spreading from bacterial infection sites with spatiotemporal fidelity. SalicS1 unlocks precise understanding of SA dynamics underpinning crop resilience to pathogens.

Topics & Concepts

Salicylic acidBiologyEndogenyFörster resonance energy transferImmune systemCell biologyHormoneIn vivoComputational biologyDynamics (music)PathogenChemistryOrganismArabidopsisSystemic acquired resistanceFluorescenceBiophysicsEnergy transferAdaptive responseBiochemistryPlant hormoneModel organismPlant-Microbe Interactions and ImmunityPlant Virus Research StudiesPlant Pathogenic Bacteria Studies