Abstract
Pseudomonas syringae is a destructive bacterial pathogen that infects a wide variety of plants. Following apoplastic entry, P. syringae uses its type 3 injectisome (T3I) to secrete host-specific effectors into the cytoplasm, enabling tissue wetting and immune suppression and leading to bacterial proliferation, chlorosis and necrosis. P. syringae strains encode dozens of highly specialised effectors, whose composition defines strain specificity and host range. Effective plant infection depends on the tight temporal and hierarchical control of effector delivery through the T3I. Effector secretion is driven by HrcN, an ATPase complex that interacts with the base of the T3I and is essential for plant infection. HrcN binds specifically to the bacterial signalling molecule cyclic-di-GMP, although the impact of binding on T3I function and P. syringae virulence is currently unknown. To address this, we examined the influence of mutating the predicted cyclic-di-GMP-hrcN binding site on plant infection and effector secretion. Despite maintaining effective bacterial proliferation in Arabidopsis thaliana leaves, two hrcN mutants showed severely compromised disease symptoms, a phenotype linked to reduced translocation of a specific subset of T3I-effectors, with HopAA1-2 particularly important for symptom development. We propose that cyclic-di-GMP binding may represent a novel regulatory mechanism for effector secretion during bacterial infections.