A regulatory network promotes apoplastic alkalinization to prime plant immunity in tissues distal to site of infection
Summary
Immune activation in plants triggers extracellular alkalinization, presumably by inhibiting plasma membrane H+-ATPases. The precise role and underlying mechanisms of this process remain poorly understood. Here, we show that Pseudomonas syringae bacteria induce apoplastic alkalinization not only at the site of infection but also in neighboring distal tissues to prime defenses and disease resistance in Arabidopsis. We show that several calcium-dependent protein kinases phosphorylate Ser899 o
Content
# A regulatory network promotes apoplastic alkalinization to prime plant immunity in tissues distal to site of infection
*Published: 2026 Mar 5*
Immune activation in plants triggers extracellular alkalinization, presumably by
inhibiting plasma membrane H+-ATPases. The precise role and underlying
mechanisms of this process remain poorly understood. Here, we show that
Pseudomonas syringae bacteria induce apoplastic alkalinization not only at the
site of infection but also in neighboring distal tissues to prime defenses and
disease resistance in Arabidopsis. We show that several calcium-dependent
protein kinases phosphorylate Ser899 of two major autoinhibited H+-ATPases to
dampen their activity, leading to alkalinization. The distal alkalinization is
accompanied by the transcriptional activation of phytocytokines, including plant
elicitor peptides, serine-rich endogenous peptides, and their receptors. We show
that these phytocytokines promote distal alkalinization and disease resistance,
whereas the apoplastic alkalinization sensitizes the phytocytokine perception
that further induces phytocytokine genes. Our study suggests that apoplastic
alkalinization and phytocytokine gene expression mutually potentiate and act as
a combined signal that propagates in local-distal communication and disease
resistance priming.
DOI: 10.1016/j.cell.2026.01.027