Abstract
Despite intensive breeding efforts, potato late blight, caused by the oomycete pathogen Phytophthora infestans, remains a threat to potato production worldwide because newly evolved pathogen strains have consistently overcome major resistance genes. The potato RB gene, derived from the wild species Solanum bulbocastanum, confers resistance to most P. infestans strains through recognition of members of the pathogen effector family IPI-O. While the majority of IPI-O proteins are recognized by RB to elicit resistance (e.g. IPI-O1, IPI-O2), some family members are able to elude detection (e.g. IPI-O4). In addition, IPI-O4 blocks recognition of IPI-O1, leading to inactivation of RB-mediated programmed cell death. Here, we report results that elucidate molecular mechanisms governing resistance elicitation or suppression of RB by IPI-O. Our data indicate self-association of the RB coiled coil (CC) domain as well as a physical interaction between this domain and the effectors IPI-O4 and IPI-O1. We identified four amino acids within IPI-O that are critical for interaction with the RB CC domain and one of these amino acids, at position 129, determines hypersensitive response (HR) elicitation in planta. IPI-O1 mutant L129P fails to induce HR in presence of RB while IPI-O4 P129L gains the ability to induce an HR. Like IPI-O4, IPI-O1 L129P is also able to suppress the HR mediated by RB, indicating a critical step in the evolution of this gene family. Our results point to a model in which IPI-O effectors can affect RB function through interaction with the RB CC domain.
Highlights
Plant resistance to microbial pathogens is a complex process and includes a variety of constitutive and inducible defense mechanisms [1]
Our findings suggest a model in which IPI-O4 is able to affect RB function through interaction with the coiled coil (CC) domain, possibly disrupting interactions that would otherwise lead to R protein activation
Self-association of the CC domain was observed, but no self-association was detected among the nucleotide binding (NB), leucine-rich repeat (LRR) or CCNB domains (Figure 1A)
Summary
Plant resistance to microbial pathogens is a complex process and includes a variety of constitutive and inducible defense mechanisms [1]. Recognition and response to microbes by plants involve multiple layers of defense. The first, basal defense, relies on the recognition of conserved microbial associated molecular patterns by host receptors [2]. The basal defense response can be suppressed by pathogen proteins, termed effectors, that are delivered into the apoplast or plant cell cytoplasm, resulting in effector triggered susceptibility [3,4,5]. Plants have evolved a second layer of defense, called effector triggered immunity (ETI), in which host protein receptors recognize the presence of pathogen effectors and elicit responses to inhibit colonization [6]. ETI relies on resistance (R) proteins to directly or indirectly recognize the presence of specific effector molecules and activate resistance signaling
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