Computational and Biochemical Analysis of the Xanthomonas Effector AvrBs2 and Its Role in the Modulation of Xanthomonas Type Three Effector Delivery

Effectors of the bacterial type III secretion system provide invaluable molecular probes to elucidate the molecular mechanisms of plant immunity and pathogen virulence. In this report, we focus on the AvrBs2 effector protein from the bacterial pathogen Xanthomonas euvesicatoria (Xe), the causal agent of bacterial spot disease of tomato and pepper. Employing homology-based structural analysis, we generate a three-dimensional structural model for the AvrBs2 protein and identify catalytic sites in its putative glycerolphosphodiesterase domain (GDE). We demonstrate that the identified catalytic region of AvrBs2 was able to functionally replace the GDE catalytic site of the bacterial glycerophosphodiesterase BhGlpQ cloned from Borrelia hermsii and is required for AvrBs2 virulence. Mutations in the GDE catalytic domain did not disrupt the recognition of AvrBs2 by the cognate plant resistance gene Bs2. In addition, AvrBs2 activation of Bs2 suppressed subsequent delivery of other Xanthomonas type III effectors into the host plant cells. Investigation of the mechanism underlying this modulation of the type III secretion system may offer new strategies to generate broad-spectrum resistance to bacterial pathogens

Global Analysis of Arabidopsis/Downy Mildew Interactions Reveals Prevalence of Incomplete Resistance and Rapid Evolution of Pathogen Recognition

Interactions between Arabidopsis thaliana and its native obligate oomycete pathogen Hyaloperonospora arabidopsidis (Hpa) represent a model system to study evolution of natural variation in a host/pathogen interaction. Both Arabidopsis and Hpa genomes are sequenced and collections of different sub-species are available. We analyzed ∼400 interactions between different Arabidopsis accessions and five strains of Hpa. We examined the pathogen's overall ability to reproduce on a given host, and performed detailed cytological staining to assay for pathogen growth and hypersensitive cell death response in the host. We demonstrate that intermediate levels of resistance are prevalent among Arabidopsis populations and correlate strongly with host developmental stage. In addition to looking at plant responses to challenge by whole pathogen inoculations, we investigated the Arabidopsis resistance attributed to recognition of the individual Hpa effectors, ATR1 and ATR13. Our results suggest that recognition of these effectors is evolutionarily dynamic and does not form a single clade in overall Arabidopsis phylogeny for either effector. Furthermore, we show that the ultimate outcome of the interactions can be modified by the pathogen, despite a defined gene-for-gene resistance in the host. These data indicate that the outcome of disease and disease resistance depends on genome-for-genome interactions between the host and its pathogen, rather than single gene pairs as thought previously

Computational Prediction and Molecular Characterization of an Oomycete Effector and the Cognate Arabidopsis Resistance Gene

Hyaloperonospora arabidopsidis (Hpa) is an obligate biotroph oomycete pathogen of the model plant Arabidopsis thaliana and contains a large set of effector proteins that are translocated to the host to exert virulence functions or trigger immune responses. These effectors are characterized by conserved amino-terminal translocation sequences and highly divergent carboxyl-terminal functional domains. The availability of the Hpa genome sequence allowed the computational prediction of effectors and the development of effector delivery systems enabled validation of the predicted effectors in Arabidopsis. In this study, we identified a novel effector ATR39-1 by computational methods, which was found to trigger a resistance response in the Arabidopsis ecotype Weiningen (Wei-0). The allelic variant of this effector, ATR39-2, is not recognized, and two amino acid residues were identified and shown to be critical for this loss of recognition. The resistance protein responsible for recognition of the ATR39-1 effector in Arabidopsis is RPP39 and was identified by map-based cloning. RPP39 is a member of the CC-NBS-LRR family of resistance proteins and requires the signaling gene NDR1 for full activity. Recognition of ATR39-1 in Wei-0 does not inhibit growth of Hpa strains expressing the effector, suggesting complex mechanisms of pathogen evasion of recognition, and is similar to what has been shown in several other cases of plant-oomycete interactions. Identification of this resistance gene/effector pair adds to our knowledge of plant resistance mechanisms and provides the basis for further functional analyses

Structural Elucidation and Functional Characterization of the Hyaloperonospora arabidopsidis Effector Protein ATR13

The oomycete Hyaloperonospora arabidopsidis (Hpa) is the causal agent of downy mildew on the model plant Arabidopsis thaliana and has been adapted as a model system to investigate pathogen virulence strategies and plant disease resistance mechanisms. Recognition of Hpa infection occurs when plant resistance proteins (R-genes) detect the presence or activity of pathogen-derived protein effectors delivered to the plant host. This study examines the Hpa effector ATR13 Emco5 and its recognition by RPP13-Nd, the cognate R-gene that triggers programmed cell death (HR) in the presence of recognized ATR13 variants. Herein, we use NMR to solve the backbone structure of ATR13 Emco5, revealing both a helical domain and a disordered internal loop. Additionally, we use site-directed and random mutagenesis to identify several amino acid residues involved in the recognition response conferred by RPP13-Nd. Using our structure as a scaffold, we map these residues to one of two surface-exposed patches of residues under diversifying selection. Exploring possible roles of the disordered region within the ATR13 structure, we perform domain swapping experiments and identify a peptide sequence involved in nucleolar localization. We conclude that ATR13 is a highly dynamic protein with no clear structural homologues that contains two surface-exposed patches of polymorphism, only one of which is involved in RPP13-Nd recognition specificity

NDR1 Interaction with RIN4 Mediates the Differential Activation of Multiple Disease Resistance Pathways in Arabidopsis

Recognition of pathogens by plants involves the coordinated efforts of molecular chaperones, disease resistance (R) proteins, and components of disease resistance signaling pathways. Characterization of events associated with pathogen perception in Arabidopsis thaliana has advanced understanding of molecular genetic mechanisms associated with disease resistance and protein interactions critical for the activation of resistance signaling. Regulation of R protein–mediated signaling in response to the bacterial pathogen Pseudomonas syringae in Arabidopsis involves the physical association of at least two R proteins with the negative regulator RPM1 INTERACTING PROTEIN4 (RIN4). While the RIN4-RPS2 (for RESISTANCE TO P. SYRINGAE2) and RIN4-RPM1 (for RESISTANCE TO P. SYRINGAE PV MACULICOLA1) signaling pathways exhibit differential mechanisms of activation in terms of effector action, the requirement for NON-RACE-SPECIFIC DISEASE RESISTANCE1 (NDR1) is shared. Using a yeast two-hybrid screen, followed by a series of coimmunoprecipitation experiments, we demonstrate that the RIN4–NDR1 interaction occurs on the cytoplasmically localized N-terminal portion of NDR1 and that this interaction is required for the activation of resistance signaling following infection by P. syringae expressing the Cys protease Type III effector protein AvrRpt2. We demonstrate that like RPS2 and RPM1, NDR1 also associates with RIN4 in planta. We suggest that this interaction serves to further regulate activation of disease resistance signaling following recognition of P. syringae DC3000-AvrRpt2 by Arabidopsis

Molecular Basis for the RIN4 Negative Regulation of RPS2 Disease Resistance

Recent studies have demonstrated that RPS2, a plasma membrane–localized nucleotide binding site/leucine-rich repeat protein from Arabidopsis thaliana, associates with RPM1 Interacting Protein 4 (RIN4) and that this association functions to modulate the RPS2-mediated defense pathway in response to the bacterial effector protein AvrRpt2. In addition to negatively regulating RPS2 activity, RIN4 is also a target of AvrRpt2, a Cys protease and cognate bacterial effector protein of RPS2. Nicotiana benthamiana has been employed as a heterologous expression system to characterize the RPS2–RIN4 association, defining the domains in RIN4 required for the negative regulation of RPS2 activity. Upon inoculation of N. benthamiana leaves with Agrobacterium tumefaciens expressing RPS2, a rapid hypersensitive response (HR) is detected with 22 h of infiltration. The HR can be blocked by infiltrating the leaf with A. tumefaciens expressing RPS2 in the presence of RIN4, recapitulating the ability of RIN4 to interfere with RPS2-mediated resistance in Arabidopsis. Moreover, in the presence of RIN4, the RPS2-mediated HR can be restored by the delivery of AvrRpt2 via A. tumefaciens. This assay has been developed as a phenotypic marker for (1) the HR-inducing phenotype associated with RPS2, (2) negative regulation of RPS2 by RIN4, and (3) the AvrRpt2-mediated disappearance of RIN4. Here, we present a series of deletion and site-directed mutation analyses to identify amino acids in RIN4 required for the RPS2–RIN4 association and to distinguish these from residues in RIN4 that serve as a target sequence for AvrRpt2. In addition to characterizing the RPS2–RIN4 association in N. benthamiana, we have moved forward to show that the biological relevance of these amino acid changes is applicable in Arabidopsis as well. To this end, we have identified specific amino acids within the C-terminal half of RIN4 that are required for RPS2 regulation and association