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ABSTRACT Recognizing pathogen-associated molecular patterns (PAMPs) on the cell surface is crucial for plant immunity. The proteinaceous nature of many of these patterns suggests that secreted proteases play important roles in their formation and stability. Here, we demonstrate that the apoplastic subtilase SBT5.2a inactivates the immunogenicity of cold-shock proteins of the bacterial plant pathogen Pseudomonas syringae by cleaving within the immunogenic csp22 epitope. Consequently, mutant plants lacking SBT5.2a activity retain higher levels of csp22, leading to enhanced immune responses and reduced pathogen growth. SBT5.2 sensitivity is influenced by sequence variation surrounding the cleavage site and likely extends to CSPs from other bacterial species. These findings suggest that variations in csp22 stability among bacterial pathogens are a crucial factor in plant-bacteria interactions and that pathogens might exploit plant proteases to avoid pattern recognition.
Chen et al. (Fri,) studied this question.