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High humidity has a strong influence on the development of numerous diseases affecting the above-ground parts of plants (the phyllosphere) in crop fields and natural ecosystems, but the molecular basis of this humidity effect is not understood. Previous studies have emphasized immune suppression as a key step in bacterial pathogenesis. Here we show that humidity-dependent, pathogen-driven establishment of an aqueous intercellular space (apoplast) is another important step in bacterial infection of the phyllosphere. Bacterial effectors, such as Pseudomonas syringae HopM1, induce establishment of the aqueous apoplast and are sufficient to transform non-pathogenic P. syringae strains into virulent pathogens in immunodeficient Arabidopsis thaliana under high humidity. Arabidopsis quadruple mutants simultaneously defective in a host target (AtMIN7) of HopM1 and in pattern-triggered immunity could not only be used to reconstitute the basic features of bacterial infection, but also exhibited humidity-dependent dyshomeostasis of the endophytic commensal bacterial community in the phyllosphere. These results highlight a new conceptual framework for understanding diverse phyllosphere–bacterial interactions. A combination of high humidity and bacterial effectors, such as Pseudomonas syringae HopM1, creates an aqueous environment in the apoplast of immunodeficient Arabidopsis thaliana that allows non-pathogenic P. syringae strains to become virulent pathogens. Bacterial pathogenesis in plants High humidity has a profound influence on the development of numerous plant diseases in crop fields and natural ecosystems, but the molecular basis of this humidity effect is not understood. Sheng Yang He and colleagues show that plant pathogens such as Pseudomonas syringae actively establish an aqueous leaf apoplast—that is, a space between the cells and the cell walls—in a humidity-dependent manner through the secretion of conserved bacterial effectors. The effectors also cause alterations in the leaf-associated microbiota. This is a crucial step in plant infection by bacteria and the effectors involved are sufficient to transform non-pathogenic strains into virulent pathogens only under high humidity. Through elegant genetics work, the authors define immune suppression and aqueous apoplast formation as the minimal set of host processes required for bacterial pathogenesis in plant leaves.

The plant immune system involves cell-surface receptors that detect intercellular pathogen-derived molecules, and intracellular receptors that activate immunity upon detection of pathogen-secreted effector proteins that act inside the plant cell. Immunity mediated by surface receptors has been extensively studied 1 , but that mediated by intracellular receptors has rarely been investigated in the absence of surface-receptor-mediated immunity. Furthermore, interactions between these two immune pathways are poorly understood. Here, by activating intracellular receptors without inducing surface-receptor-mediated immunity, we analyse interactions between these two distinct immune systems in Arabidopsis . Pathogen recognition by surface receptors activates multiple protein kinases and NADPH oxidases, and we find that intracellular receptors primarily potentiate the activation of these proteins by increasing their abundance through several mechanisms. Likewise, the hypersensitive response that depends on intracellular receptors is strongly enhanced by the activation of surface receptors. Activation of either immune system alone is insufficient to provide effective resistance against the bacterial pathogen Pseudomonas syringae . Thus, immune pathways activated by cell-surface and intracellular receptors in plants mutually potentiate to activate strong defences against pathogens. These findings reshape our understanding of plant immunity and have broad implications for crop improvement. In Arabidopsis , two distinct types of immunity—that mediated by cell-surface receptors and that mediated by intracellular receptors—interact with and mutually enhance each other to provide effective defence against pathogens.

Understanding local adaptation of phytopathogens has significant practical and economic implications. The opportunistic pathogen Pseudomonas syringae exemplifies this challenge, causing regular epidemics in diverse host plants. Many pathogenic microbes, including P. syringae , are divided into intraspecific lineages, or pathovars, based on their host-of-isolation. However, whether pathovar classifications reflect adaptation of the pathogen to the host (local adaptation) or a competitive advantage of the pathogen in the host (local dominance), often goes untested. In this study, we performed in vitro growth assays and factorial controlled infections to test whether a suite of five P. syringae pathovars are locally adapted to, and/or locally dominant in, their hosts-of-isolation. We found evidence of local adaptation in three of five pathogens, only one of which was also locally dominant. Several strains performed as well or better than the locally adapted strain in that strain’s host-of-isolation, consistent with cost-free generalism. Thus, pathovar designations do not reliably delineate pathogenic phenotypes. Moreover, we found that in vitro growth was not predictive of in planta growth. To contextualize phenotypes, we compared pathogen gene content, identifying unique phytotoxins, secreted effectors, and general virulence factors. In all, we found that local adaptation is common but not universal, and that locally adapted strains are not necessarily constrained from performing competitively in multiple hosts. Thus, neither host-of-isolation nor in vitro performance is reliable for strain classification. Our findings highlight the vast intraspecific variation in P. syringae , and the coexistence of multiple successful adaptive strategies.

The bacterial pathogen Pseudomonas syringae modulates plant hormone signaling to promote infection and disease development. P. syringae uses several strategies to manipulate auxin physiology in Arabidopsis thaliana to promote pathogenesis, including its synthesis of indole-3-acetic acid (IAA), the predominant form of auxin in plants, and production of virulence factors that alter auxin responses in the host; however, the role of pathogen-derived auxin in P. syringae pathogenesis is not well understood. Here we demonstrate that P. syringae strain DC3000 produces IAA via a previously uncharacterized pathway and identify a novel indole-3-acetaldehyde dehydrogenase, AldA, that functions in IAA biosynthesis by catalyzing the NAD-dependent formation of IAA from indole-3-acetaldehyde (IAAld). Biochemical analysis and solving of the 1.9 Å resolution x-ray crystal structure reveal key features of AldA for IAA synthesis, including the molecular basis of substrate specificity. Disruption of aldA and a close homolog, aldB, lead to reduced IAA production in culture and reduced virulence on A. thaliana. We use these mutants to explore the mechanism by which pathogen-derived auxin contributes to virulence and show that IAA produced by DC3000 suppresses salicylic acid-mediated defenses in A. thaliana. Thus, auxin is a DC3000 virulence factor that promotes pathogenicity by suppressing host defenses.

Pseudomonas syringae is one of the best-studied plant pathogens and serves as a model for understanding host-microorganism interactions, bacterial virulence mechanisms and host adaptation of pathogens as well as microbial evolution, ecology and epidemiology. Comparative genomic studies have identified key genomic features that contribute to P. syringae virulence. P. syringae has evolved two main virulence strategies: suppression of host immunity and creation of an aqueous apoplast to form its niche in the phyllosphere. In addition, external environmental conditions such as humidity profoundly influence infection. P. syringae may serve as an excellent model to understand virulence and also of how pathogenic microorganisms integrate environmental conditions and plant microbiota to become ecologically robust and diverse pathogens of the plant kingdom.

The complete genomic sequence of Pseudomonas syringae pv. syringae B728a (Pss B728a) has been determined and is compared with that of P. syringae pv. tomato DC3000 (Pst DC3000). The two pathovars of this economically important species of plant pathogenic bacteria differ in host range and other interactions with plants, with Pss having a more pronounced epiphytic stage of growth and higher abiotic stress tolerance and Pst DC3000 having a more pronounced apoplastic growth habitat. The Pss B728a genome (6.1 Mb) contains a circular chromosome and no plasmid, whereas the Pst DC3000 genome is 6.5 mbp in size, composed of a circular chromosome and two plasmids. Although a high degree of similarity exists between the two sequenced Pseudomonads, 976 protein-encoding genes are unique to Pss B728a when compared with Pst DC3000, including large genomic islands likely to contribute to virulence and host specificity. Over 375 repetitive extragenic palindromic sequences unique to Pss B728a when compared with Pst DC3000 are widely distributed throughout the chromosome except in 14 genomic islands, which generally had lower GC content than the genome as a whole. Content of the genomic islands varies, with one containing a prophage and another the plasmid pKLC102 of Pseudomonas aeruginosa PAO1. Among the 976 genes of Pss B728a with no counterpart in Pst DC3000 are those encoding for syringopeptin, syringomycin, indole acetic acid biosynthesis, arginine degradation, and production of ice nuclei. The genomic comparison suggests that several unique genes for Pss B728a such as ectoine synthase, DNA repair, and antibiotic production may contribute to the epiphytic fitness and stress tolerance of this organism.

Plants are continuously threatened by pathogen attack and, as such, they have evolved mechanisms to evade, escape and defend themselves against pathogens. However, it is not known what types of defense mechanisms a plant would already possess to defend against a potential pathogen that has not co-evolved with the plant. We addressed this important question in a comprehensive manner by studying the responses of 1041 accessions of Arabidopsis thaliana to the foliar pathogen Pseudomonas syringae pv. tomato (Pst) DC3000. We characterized the interaction using a variety of established methods, including different inoculation techniques, bacterial mutant strains, and assays for the hypersensitive response, salicylic acid (SA) accumulation and reactive oxygen species production. Fourteen accessions showed resistance to infection by Pst DC3000. Of these, two accessions had a surface-based mechanism of resistance, six showed a hypersensitive-like response while three had elevated SA levels. Interestingly, A. thaliana was discovered to have a recognition system for the effector AvrPto, and HopAM1 was found to modulate Pst DC3000 resistance in two accessions. Our comprehensive study has significant implications for the understanding of natural disease resistance mechanisms at the species level and for the ecology and evolution of plant–pathogen interactions.

Summary Bacterial canker of kiwifruit, is a severe global disease caused by Pseudomonas syringae pv. actinidiae (Psa). Here, we found that Psa biovar 3 (Psa3) was the only biovar consisting of three widely distributed clades in the largest Chinese kiwifruit cultivated area. Comparative genomics between the three clades revealed 13 polymorphic genes, each of which had multiple intra‐clade variations. For instance, we confirmed that the polymorphic copA gene, which encodes a periplasmic protein CopA that is translocated by the Twin‐arginine targeting (Tat) system, was involved in copper tolerance. We also found extensive variation in pathogenicity amongst strains within each genetically monomorphic clade. Accordingly, the pathogenic determinants of Psa3 were identified via a genomic comparison of phenotypically different strains within each clade. A case study of the high‐ and low‐virulence strains in the clade 2 of Psa3 revealed that an hfq variant involved in in vitro growth and virulence, while a conserved locus 930 bp upstream of the hrpR gene in the Type III secretion system (T3SS) cluster was required for full pathogenicity on kiwifruit and elicitation of the hypersensitivity response on non‐host Nicotiana benthamiana. The ‘‐930’ locus is involved in transcriptional regulation of hrpR/S and modulates T3SS function via the hierarchical ‘HrpR/S‐HrpL‐T3SS/effector’ regulatory cascade in Psa. Our results provide insights into the molecular basis underlying the genetic diversification and evolution of pathogenicity in Psa3 since kiwifruit canker emerged in China in the 1980s.

Bacterial blight (causal agent Pseudomonas syringae complex, Psc) is an endemic and economically important disease of northern highbush blueberry production in Canada and the Pacific Northwest of the USA. To date, there is no comprehensive survey of the disease in the region and detailed characterization of associated pathogens from Pacific western Canada. Therefore, we did comprehensive disease survey and characterization of associated pseudomonads population using pathogen morphology, biochemical tests, and molecular characterization. We isolated 380 strains of pseudomonads from symptomatic plants from 32 research and commercial fields in 10 diverse geographic locations in British Columbia. We used P . syringae specific (Psy) primers and identified 197 Psy-PCR positive isolates out of 380. We further sequenced Psy-PCR positive isolates of pseudomonads using four housekeeping genes and identified four phylogenomic species: P. syringae (40%), Pseudomonas avellanae (29%), Pseudomonas viridiflava (20%), and phylogenomic species A (7%). P . avellanae and P. viridiflava are new phylogenomic species of Psc causing bacterial blight in highbush blueberry. We found some patterns among geographical locations and highbush blueberry varieties in the frequency distribution of isolates of these phylogenomic species. Genetic fingerprinting with rep-PCR assays identified a very high genetic diversity of pseudomonads populations among geographical locations, varieties, and phylogenomic species. Biochemical characterization (LOPAT- levan, oxidase, pectolytic activity, arginine dihydrolase, and tobacco hypersensitivity) revealed that the vast majority of isolates were Pseudomonas Group Ia. Findings of this study provide insight into the population biology of pseudomonads infecting highbush blueberry, provide information for disease diagnosis, and exploit disease management options, including identifying sources of disease resistance. Key points • High prevalence of bacterial blight caused by P. syringae complex (Psc) in highbush blueberry in Pacific western Canada • We report two new phylogenomic species of Psc, P. viridiflava and P. avellanae, that cause bacterial blight and canker disease in highbush blueberry • The genetic diversity of the population of Psc was very high

Effector-triggered immunity (ETI), induced by host immune receptors in response to microbial effectors, protects plants against virulent pathogens. However, a systematic study of ETI prevalence against species-wide pathogen diversity is lacking. We constructed the Pseudomonas syringae Type III Effector Compendium (PsyTEC) to reduce the pan-genome complexity of 5127 unique effector proteins, distributed among 70 families from 494 strains, to 529 representative alleles. We screened PsyTEC on the model plant Arabidopsis thaliana and identified 59 ETI-eliciting alleles (11.2%) from 19 families (27.1%), with orthologs distributed among 96.8% of P. syringae strains. We also identified two previously undescribed host immune receptors, including CAR1, which recognizes the conserved effectors AvrE and HopAA1, and found that 94.7% of strains harbor alleles predicted to be recognized by either CAR1 or ZAR1.