Cell wall integrity and elicitor peptide signaling modulate jasmonic acid-mediated camalexin production in Arabidopsis

Plant cell walls constitute dynamic barriers that are essential for defense against pathogens. The receptor kinase THESEUS1 (THE1) monitors cell wall integrity (CWI) and contributes to pathogen resistance in Arabidopsis, but the underlying mechanisms remain unclear. Here we show that THE1-dependent CWI signaling induces accumulation of the antimicrobial metabolite camalexin upon cell wall damage (CWD) caused by cellulose biosynthesis inhibition or fungal infection. CWD alters THE1 plasma membrane nanodomain organization and involves calcium signaling components that modulate camalexin production. Induction of camalexin requires jasmonic acid (JA)-dependent expression of the transcription factors MYB47 and MYB95. In line with its antagonistic function on CWI signaling, the plant elicitor peptide Pep3 suppresses camalexin biosynthesis downstream of THE1 by inhibiting JA-dependent pathways. Our findings reveal a regulatory network where CWI and Pep3 signaling modulate antimicrobial defense via JA-mediated camalexin production. This network requires independent CWD-induced pathways, providing insights into how plants balance defense activation and suppression in response to cell wall stress.