Disease-suppressive soils are exceptional ecosystems in which crop plants suffer less from specific soil-borne pathogens than expected owing to the activities of other soil microorganisms. For most disease-suppressive soils, the microbes and mechanisms involved in pathogen control are unknown. By coupling PhyloChip-based metagenomics of the rhizosphere microbiome with culture-dependent functional analyses, we identified key bacterial taxa and genes involved in suppression of a fungal root pathogen. More than 33,000 bacterial and archaeal species were detected, with Proteobacteria, Firmicutes, and Actinobacteria consistently associated with disease suppression. Members of the γ-Proteobacteria were shown to have disease-suppressive activity governed by nonribosomal peptide synthetases. Our data indicate that upon attack by a fungal root pathogen, plants can exploit microbial consortia from soil for protection against infections.
SUMMARY Race-specific resistance in plants against microbial pathogens is governed by several distinct classes of resistance (R) genes. This review focuses on the class that consists of the plasma membrane-bound leucine-rich repeat proteins known as receptor-like proteins (RLPs). The first isolated resistance genes of the RLP class are the tomato Cf genes, which confer resistance to the fungal pathogen Cladosporium fulvum. To date, several other RLP genes are known to be implicated in resistance in other plant-pathogen interactions. These include HcrVf2 from apple, Ve1 and Ve2 from tomato, and RPP27 from Arabidopsis, which are involved in resistance to Venturia, Verticillium and Peronospora, respectively. Furthermore, the tomato RLP gene LeEix initiates defence responses upon elicitation with a fungal ethylene-inducing xylanase (EIX) of non-pathogenic Trichoderma. The tomato Cf genes, which are the most intensively studied RLP resistance genes, are usually found in clusters of several homologues. Whereas some of these homologues are functional Cf resistance genes, others have no known function in resistance. Different evolutionary processes contribute to variation in functional Cf genes, and functional as well as non-functional homologues may provide a source for the generation of novel Cf resistance genes. To date, little is known of the proteins that interact with Cf proteins to initiate defence responses. In contrast to the LeEix protein and the corresponding EIX elicitor, for which a direct interaction was found, no direct interaction between Cf proteins and the corresponding C. fulvum elicitors has been demonstrated. Analogous to the CLAVATA signalling complex, which comprises an RLP, a receptor-like kinase (RLK) and a small proteineous ligand, Cf proteins may form a complex with RLKs and thus initiate signalling upon recognition of the corresponding elicitors. The presence of RLP resistance genes in diverse plant species suggests that these genes play an important role in the extracellular recognition of plant pathogens.
Aims: Plant growth‐promoting Pseudomonas putida strain 267, originally isolated from the rhizosphere of black pepper, produces biosurfactants that cause lysis of zoospores of the oomycete pathogen Phytophthora capsici. The biosurfactants were characterized, the biosynthesis gene(s) partially identified, and their role in control of Phytophthora damping‐off of cucumber evaluated. Methods and Results: The biosurfactants were shown to lyse zoospores of Phy. capsici and inhibit growth of the fungal pathogens Botrytis cinerea and Rhizoctonia solani. In vitro assays further showed that the biosurfactants of strain 267 are essential in swarming motility and biofilm formation. In spite of the zoosporicidal activity, the biosurfactants did not play a significant role in control of Phytophthora damping‐off of cucumber, since both wild type strain 267 and its biosurfactant‐deficient mutant were equally effective, and addition of the biosurfactants did not provide control. Genetic characterization revealed that surfactant biosynthesis in strain 267 is governed by homologues of PsoA and PsoB, two nonribosomal peptide synthetases involved in production of the cyclic lipopeptides (CLPs) putisolvin I and II. The structural relatedness of the biosurfactants of strain 267 to putisolvins I and II was supported by LC‐MS and MS‐MS analyses. Conclusions: The biosurfactants produced by Ps. putida 267 were identified as putisolvin‐like CLPs; they are essential in swarming motility and biofilm formation, and have zoosporicidal and antifungal activities. Strain 267 provides excellent biocontrol activity against Phytophthora damping‐off of cucumber, but the lipopeptide surfactants are not involved in disease suppression. Significance and Impact of the Study: Pseudomonas putida 267 suppresses Phy. capsici damping‐off of cucumber and provides a potential supplementary strategy to control this economically important oomycete pathogen. The putisolvin‐like biosurfactants exhibit zoosporicidal and antifungal activities, yet they do not contribute to biocontrol of Phy. capsici and colonization of cucumber roots by Ps. putida 267. These results suggest that Ps. putida 267 employs other, yet uncharacterized, mechanisms to suppress Phy. capsici.
Resistance gene Cf-9 of cultivated tomato (Lycopersicon esculentum) confers recognition of the AVR9 elicitor protein of the fungal pathogen Cladosporium fulvum. The Cf-9 locus, containing Cf-9 and four homologs (Hcr9s), originates from Lycopersicon pimpinellifolium (Lp). We examined naturally occurring polymorphism in Hcr9s that confer AVR9 recognition in the Lp population. AVR9 recognition occurs frequently throughout this population. In addition to Cf-9, we discovered a second gene in Lp, designated 9DC, which also confers AVR9 recognition. Compared with Cf-9, 9DC is more polymorphic, occurs more frequently, and is more widely spread throughout the Lp population, suggesting that 9DC is older than Cf-9. The sequences of Cf-9 and 9DC suggest that Cf-9 evolved from 9DC by intragenic recombination between 9DC and another Hcr9. The fact that the 9DC and Cf-9 proteins differ in 61 aa residues, and both mediate recognition of AVR9, shows that in nature Hcr9 proteins with the same recognitional specificity can vary significantly. R ecognition of a diverse range of pathogens, followed by an adequate defense response, is crucial for the survival of plants. Resistance (R) genes, which mediate recognition of products of matching avirulence (Avr) genes, play a key role in the recognition of pathogens (1). Most R gene products contain a leucine-rich repeat (LRR) domain with putative solventexposed amino acid residues that decorate the surface of the protein, where specific interactions with other proteins are thought to occur (2). R proteins with different specificities differ predominantly at putative solvent-exposed positions, which are often thought to result from adaptive evolution (3).Plants need to generate R genes with new specificities because pathogens continuously try to circumvent recognition by the host plant. New R genes are thought to evolve by sequence exchange between homologous genes and by accumulation of random point mutations in codons that encode amino acids located at putative solvent-exposed positions (3, 4).The continuous generation of new recognitional specificities by the host, followed by subsequent adaptation of the pathogen to circumvent this recognition, can be seen as an ''arms race'' between plants and pathogens (5). Recent observations suggest that in nature, this arms race is a slow process and that the battle between plants and pathogens is more likely to be similar to ''trench warfare.'' In this model, frequencies of R genes in the plant population fluctuate in time, following the frequency of the matching Avr gene in the pathogen population (6). Consistent with this model, gene-for-gene pairs like AvrRpm1-RPM1 and AvrPto-Pto are ancient (6, 7), and plants carrying or lacking the RPM1 gene coexist in the plant population (6).The tomato R genes Cf-9 and Cf-4 mediate recognition of strains of the leaf mold fungus Cladosporium fulvum carrying the Avr9 or Avr4 gene, respectively (8). Recognition by resistant plants results in the activation of multiple defense responses that limit further fun...
The Cf-4 and Cf-9 genes originate from the wild tomato species Lycopersicon hirsutum and L. pimpinellifolium and confer resistance to strains of the leaf mold fungus Cladosporium fulvum that secrete the Avr4 and Avr9 elicitor proteins, respectively. Homologs of Cf-4 and Cf-9 (Hcr9s) are located in several clusters and evolve mainly through sequence exchange between homologs. To study the evolution of Cf genes, we set out to identify functional Hcr9s that mediate recognition of Avr4 and Avr9 (designated Hcr9-Avr4s and Hcr9-Avr9s) in all wild tomato species. Plants responsive to the Avr4 and Avr9 elicitor proteins were identified throughout the genus Lycopersicon. Open reading frames of Hcr9s from Avr4- and Avr9-responsive tomato plants were polymerase chain reaction-amplified. Several Hcr9s that mediate Avr4 or Avr9 recognition were identified in diverged tomato species by agroinfiltration assays. These Hcr9-Avr4s and Hcr9-Avr9s are highly identical to Cf-4 and Cf-9, respectively. Therefore, we conclude that both Cf-4 and Cf-9 predate Lycopersicon speciation. These results further suggest that C. fulvum is an ancient pathogen of the genus Lycopersicon, in which Cf-4 and Cf-9 have been maintained by selection pressure imposed by C. fulvum.
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