Cell wall integrity and elicitor peptide signaling modulate antimicrobial defense in Arabidopsis via jasmonic acid

Cell walls provide mechanical support to plant cells during development and upon exposure to stress. Cell wall integrity (CWI) is monitored by plasma membrane-localized proteins, of which the receptor kinase THESEUS1 (THE1) has been identified as a key CWI sensor in Arabidopsis. THE1-dependent CWI signaling contributes to pathogen resistance, but the underlying mechanism is largely unknown. We report that THE1 loss-of-function mutant plants exhibited increased susceptibility to the cell wall-penetrating fungal pathogen Colletotrichum higginsianum , which was associated with reduced synthesis of the antimicrobial metabolite camalexin. Cell wall damage (CWD) caused by cellulose biosynthesis inhibition was sufficient to induce camalexin accumulation in a THE1-, WRKY33-, MPK3- and calcium-dependent manner. Based on our previous finding of coordinated CWI and plant elicitor peptide (Pep) signaling, we investigated the interaction of both pathways for camalexin accumulation. Pep3 treatment caused strong suppression of CWD-induced camalexin biosynthesis downstream of THE1 without affecting WRKY33 expression. Using RNA-Sequencing and mutant analyses, we discovered four transcription factors that were induced by CWD in a jasmonic acid (JA)- dependent manner and were under negative regulation by Pep3 signaling. We identify MYB47 as a positive regulator of camalexin biosynthesis, activated by THE1 and JA upon CWD, but suppressed by Pep3 through its inhibition of the CWD-induced JA pathway. These data show that CWI signaling is important to activate antimicrobial defense via camalexin, while the negative regulation of CWD responses by Pep3 signaling may represent a mechanism to deactivate local defense at pathogen infection sites when damage prevails.