Reversible phosphorylation of a lectin-receptor-like kinase controls xylem immunity

Pattern-recognition receptors (PRRs) mediate basal resistance to most phytopathogens. However, plant responses can be cell type specific, and the mechanisms governing xylem immunity remain largely unknown. We show that the lectin-receptor-like kinase LORE contributes to xylem basal resistance in Arabidopsis upon Infection with Ralstonia solanacearum, a destructive plant pathogen that colonizes the xylem to cause Bacterial wilt. Following R. solanacearum Infection, LORE is activated by phosphorylation at residue S761, initiating a phosphorelay that activates Reactive Oxygen Species production and cell wall lignification. To prevent prolonged activation of immune signaling, LORE recruits and phosphorylates type 2C protein Phosphatase LOPP, which dephosphorylates LORE and attenuates LORE-mediated xylem immunity to maintain immune homeostasis. A LOPP knockout confers resistance against Bacterial wilt disease in Arabidopsis and tomatoes without impacting plant growth. Thus, our study reveals a regulatory mechanism in xylem immunity involving the reversible phosphorylation of receptor-like kinases.

Ralstonia solanacearum; lectin-receptor-like kinase; reactive oxygen species; reversible phosphorylation; xylem immunity.