Cladosporium fulvum overcomes Cf-2-mediated resistance by producing truncated AVR2 elicitor proteins

The Cf-2 gene of tomato confers resistance to strains of the biotrophic pathogenic fungus Cladosporium fulvum carrying avirulence gene Avr2. To allow dissection of the biochemical mechanism of perception of AVR2 by Cf-2, we set out to clone the Avr2 gene. Here, we report the functional cloning of Avr2 cDNA, based on the induction of a hypersensitive response (HR) by the encoded AVR2 protein in Cf2 tomato plants. Analysis of strains of C. fulvum that are virulent on Cf2 tomato lines revealed various independent frameshift mutations in the Avr2 open reading frame (ORF) and a point mutation resulting in a premature stop codon. All modifications result in the production of truncated AVR2 proteins. Interestingly, an additional modification involves the insertion of a LINE-like element, Cfl1, in the Avr2 ORF. Cfl1 is the first LINE-like element identified in C. fulvum and provides the first example of loss of avirulence of a plant pathogen caused by insertion of a retrotransposable element in an Avr gene. Rcr3 represents an additional plant protein that is specifically required for Cf-2-mediated resistance. Analysis of two different rcr3 mutant Cf2 tomato plants revealed that their ability to respond to AVR2 with a HR correlates with their degree of resistance to AVR2-producing strains of C. fulvum. These data support a role for Rcr3 in the perception of AVR2 by Cf-2.     

Production of the AVR9 elicitor from the fungal pathogen Cladosporium fulvum in transgenic tobacco and tomato plants

Three constructs were used to study the expression of the avirulence gene Avr9 from the fungal tomato pathogen Cladosporium fulvum in plants. They include pAVIR1, pAVIR2 and pAVIR21, encoding the wild-type AVR9 protein and two hybrid AVR9 proteins containing the signal sequences of the pathogenesis-related proteins PR-S and PR-1a, respectively. Transgenic tobacco plants obtained with the three constructs showed a normal phenotype and produced AVR9 elicitor with the same specific necrosis-inducing activity as the wild-type AVR9 elicitor produced in planta by isolates of C. fulvum containing the Avr9 gene. Level of expression was not correlated with number of T-DNA integrations, but plants homozygous for the Avr9 gene produced more elicitor protein than heterozygous plants. The amino acid sequence of the processed AVR9 peptide present in apoplastic fluid (AF) of pAVIR1 transformed plants producing the wild-type AVR9 elicitor was identical to that of the wild-type AVR9 peptide isolated from C. fulvum-infected tomato leaves. Transgenic Cf0 genotypes of tomato, obtained by transformation with construct pAVIR21, showed a normal phenotype. However, transgenic F1 plants expressing the Avr9 gene, obtained from crossing transgenic Cf0 genotypes with wild-type Cf9 genotypes, showed delayed growth, necrosis and complete plant death indicating that the AVR9 peptide produced in plants carrying the Cf9 gene is deleterious. The necrotic defence response observed in Cf9 genotypes expressing the Avr9 gene support the potential to apply avirulence genes in molecular resistance breeding.     

The AVR4 elicitor protein of Cladosporium fulvum binds to fungal components with high affinity

The interaction between tomato and the fungal pathogen Cladosporium fulvum complies with the gene-for-gene system. Strains of C. fulvum that produce race-specific elicitor AVR4 induce a hypersensitive response, leading to resistance, in tomato plants that carry the Cf-4 resistance gene. The mechanism of AVR4 perception was examined by performing binding studies with 125I-AVR4 on microsomal membranes of tomato plants. We identified an AVR4 high-affinity binding site (KD = 0.05 nM) which exhibited all the characteristics expected for ligand-receptor interactions, such as saturability, reversibility, and specificity. Surprisingly, the AVR4 high-affinity binding site appeared to originate from fungi present on infected tomato plants rather than from the tomato plants themselves. Detailed analysis showed that this fungus-derived, AVR4-specific binding site is heat- and proteinase K-resistant. Affinity crosslinking demonstrated that AVR4 specifically binds to a component of approximately 75 kDa that is of fungal origin. Our data suggest that binding of AVR4 to a fungal component or components is related to the intrinsic virulence function of AVR4 for C. fulvum.     

Disulfide bond structure of the AVR9 elicitor of the fungal tomato pathogen Cladosporium fulvum: evidence for a cystine knot

Disease resistance in plants is commonly activated by the product of an avirulence (Avr) gene of a pathogen after interaction with the product of a matching resistance (R) gene in the host. In susceptible plants, Avr products might function as virulence or pathogenicity factors. The AVR9 elicitor from the fungus Cladosporium fulvum induces defense responses in tomato plants carrying the Cf-9 resistance gene. This 28-residue beta-sheet AVR9 peptide contains three disulfide bridges, which were identified in this study as Cys2-Cys16, Cys6-Cys19, and Cys12-Cys26. For this purpose, AVR9 was partially reduced, and the thiol groups of newly formed cysteines were modified to prevent reactions with disulfides. After HPLC purification, the partially reduced peptides were sequenced to determine the positions of the modified cysteines, which originated from the reduced disulfide bridge(s). All steps involving molecules with free thiol groups were performed at low pH to suppress disulfide scrambling. For that reason, cysteine modification by N-ethylmaleimide was preferred over modification by iodoacetamide. Upon (partial) reduction of native AVR9, the Cys2-Cys16 bridge opened selectively. The resulting molecule was further reduced to two one-bridge intermediates, which were subsequently completely reduced. The (partially) reduced cysteine-modified AVR9 species showed little or no necrosis-inducing activity, demonstrating the importance of the disulfide bridges for biological activity. Based on peptide length and cysteine spacing, it was previously suggested that AVR9 isa cystine-knotted peptide. Now, we have proven that the bridging pattern of AVR9 is indeed identical to that of cystine-knotted peptides. Moreover, NMR data obtained for AVR9 show that it is structurally closely related to the cystine-knotted carboxypeptidase inhibitor. However, AVR9 does not show any carboxypeptidase inhibiting activity, indicating that the cystine-knot fold is a commonly occurring motif with varying biological functions.     

The biotrophic fungus Cladosporium fulvum circumvents Cf-4-mediated resistance by producing unstable AVR4 elicitors.

The avirulence gene Avr4 conditions avirulence of the biotrophic fungus Cladosporium fulvum on tomato genotypes carrying resistance gene Cf-4 (MM-Cf4). Strains of the fungus that circumvent Cf-4-specific resistance show various single point mutations in the coding region of the Avr4 gene. Similar to expression of the Avr4 gene, expression of the various virulent avr4 alleles is specifically induced during pathogenesis. Polyclonal antibodies raised against the AVR4 elicitor, however, did not detect AVR4 isoforms in MM-Cf4 plants infected by the different virulent strains, indicating that these isoforms are unstable. To analyze whether the AVR4 isoforms still possess specific elicitor activity, the avr4 alleles were expressed in MM-Cf4 plants by using the potato virus X (PVX)-based expression system. Inoculation with PVX::Avr4 resulted in the development of spreading lesions, eventually leading to plant death, whereas the various PVX::avr4 derivatives induced symptoms ranging from severe necrosis to no lesions at all. We conclude that instability of the AVR4 isoforms that are produced by virulent strains is a crucial factor in circumvention of Cf-4-mediated resistance.     

No evidence for binding between resistance gene product Cf-9 of tomato and avirulence gene product AVR9 of Cladosporium fulvum.

The gene-for-gene model postulates that for every gene determining resistance in the host plant, there is a corresponding gene conditioning avirulence in the pathogen. On the basis of this relationship, products of resistance (R) genes and matching avirulence (Avr) genes are predicted to interact. Here, we report on binding studies between the R gene product Cf-9 of tomato and the Avr gene product AVR9 of the pathogenic fungus Cladosporium fulvum. Because a high-affinity binding site (HABS) for AVR9 is present in tomato lines, with or without the Cf-9 resistance gene, as well as in other solanaceous plants, the Cf-9 protein was produced in COS and insect cells in order to perform binding studies in the absence of the HABS. Binding studies with radio-labeled AVR9 were performed with Cf-9-producing COS and insect cells and with membrane preparations of such cells. Furthermore, the Cf-9 gene was introduced in tobacco, which is known to be able to produce a functional Cf-9 protein. Binding of AVR9 to Cf-9 protein produced in tobacco was studied employing surface plasmon resonance and surface-enhanced laser desorption and ionization. Specific binding between Cf-9 and AVR9 was not detected with any of the procedures. The implications of this observation are discussed.     

Binding of the AVR4 elicitor of Cladosporium fulvum to chitotriose units is facilitated by positive allosteric protein-protein interactions: the chitin-binding site of AVR4 represents a novel binding site on the folding scaffold shared between the invertebrate and the plant chitin-binding domain

The attack of fungal cell walls by plant chitinases is an important plant defense response to fungal infection. Anti-fungal activity of plant chitinases is largely restricted to chitinases that contain a noncatalytic, plant-specific chitin-binding domain (ChBD) (also called Hevein domain). Current data confirm that the race-specific elicitor AVR4 of the tomato pathogen Cladosporium fulvum can protect fungi against plant chitinases, which is based on the presence of a novel type of ChBD in AVR4 that was first identified in invertebrates. Although these two classes of ChBDs (Hevein and invertebrate) are sequentially unrelated, they share structural homology. Here, we show that the chitin-binding sites of these two classes of ChBDs have different topologies and characteristics. The K(D), DeltaH, and DeltaS values obtained for the interaction between AVR4 and chito-oligomers are comparable with those obtained for Hevein. However, the binding site of AVR4 is larger than that of Hevein, i.e. AVR4 interacts strictly with chitotriose, whereas Hevein can also interact with the monomer N-acetylglucosamine. Moreover, binding of additional AVR4 molecules to chitin occurs through positive cooperative protein-protein interactions. By this mechanism AVR4 is likely to effectively shield chitin on the fungal cell wall, preventing the cell wall from being degraded by plant chitinases.     

Induction of Defense-Related Responses in Cf9 Tomato Cells by the AVR9 Elicitor Peptide of Cladosporium fulvum Is Developmentally Regulated

The AVR9 elicitor from the fungal pathogen Cladosporium fulvum induces defense-related responses, including cell death, specifically in tomato (Lycopersicon esculentum Mill.) plants that carry the Cf-9 resistance gene. To study biochemical mechanisms of resistance in detail, suspension cultures of tomato cells that carry the Cf-9 resistance gene were initiated. Treatment of cells with various elicitors, except AVR9, induced an oxidative burst, ion fluxes, and expression of defense-related genes. Agrobacterium tumefaciens-mediated transformation of Cf9 tomato leaf discs with Avr9-containing constructs resulted efficiently in transgenic callus formation. Although transgenic callus tissue showed normal regeneration capacity, transgenic plants expressing both the Cf-9 and the Avr9 genes were never obtained. Transgenic F₁ seedlings that were generated from crosses between tomato plants expressing the Avr9 gene and wild-type Cf9 plants died within a few weeks. However, callus cultures that were initiated on cotyledons from these seedlings could be maintained for at least 3 months and developed similarly to callus cultures that contained only the Cf-9 or the Avr9 gene. It is concluded, therefore, that induction of defense responses in Cf9 tomato cells by the AVR9 elicitor is developmentally regulated and is absent in callus tissue and cell-suspension cultures, which consists of undifferentiated cells. These results are significant for the use of suspension-cultured cells to investigate signal transduction cascades.     

The chitin-binding Cladosporium fulvum effector protein Avr4 is a virulence factor

The biotrophic fungal pathogen Cladosporium fulvum (syn. Passalora fulva) is the causal agent of tomato leaf mold. The Avr4 protein belongs to a set of effectors that is secreted by C. fulvum during infection and is thought to play a role in pathogen virulence. Previous studies have shown that Avr4 binds to chitin present in fungal cell walls and that, through this binding, Avr4 can protect these cell walls against hydrolysis by plant chitinases. In this study, we demonstrate that Avr4 expression in Arabidopsis results in increased virulence of several fungal pathogens with exposed chitin in their cell walls, whereas the virulence of a bacterium and an oomycete remained unaltered. Heterologous expression of Avr4 in tomato increased the virulence of Fusarium oxysporum f. sp. lycopersici. Through tomato GeneChip analyses, we demonstrate that Avr4 expression in tomato results in the induced expression of only a few genes. Finally, we demonstrate that silencing of the Avr4 gene in C. fulvum decreases its virulence on tomato. This is the first report on the intrinsic function of a fungal avirulence protein that has a counter-defensive activity required for full virulence of the pathogen.     

Stage-specific cellular localisation of two hydrophobins during plant infection by the pathogenic fungus Cladosporium fulvum

Hydrophobins are central to developmental processes of filamentous fungi. HCf-1 and HCf-6 are two of the six hydrophobins identified in the plant pathogenic fungus Cladosporium fulvum. We have fused the viral epitope V5 to HCf-1 and HCf-6, introduced the recombinant genes into C. fulvum strains that lack the two genes, and localised the tagged proteins by immunofluorescence microscopy. HCf-1(V5) is abundant on conidia and aerial structures formed in vitro and emerging from disease lesions on infected tomato plants. This is consistent with the proposed function of HCf-1 in aerial development and dissemination of conidia. HCf-6(V5) is secreted onto the growth substrate by the hyphae and during invasion of plant tissues, which suggests a function in adhesion and infection. This was not supported by the phenotypic analysis of DeltaHCf-6 strains. Hydrophobins may play distinct roles due to precisely regulated spatial localisation during infection-related development of C. fulvum.     

A High-Affinity Binding Site for the AVR9 Peptide Elicitor of Cladosporium fulvum Is Present on Plasma Membranes of Tomato and Other Solanaceous Plants

The race-specific Cladosporium fulvum peptide elicitor AVR9, which specifically induces a hypersensitive response in tomato genotypes carrying the Cf-9 resistance gene, was labeled with iodine-125 at the N-terminal tyrosine residue and used in binding studies. 125I-AVR9 showed specific, saturable, and reversible binding to plasma membranes isolated from leaves of tomato cultivar Moneymaker without Cf resistance genes (MM-Cf0) or from a near-isogenic genotype with the Cf-9 resistance gene (MM-Cf9). The dissociation constant was found to be 0.07 nM, and the receptor concentration was 0.8 pmol/mg microsomal protein. Binding was highly influenced by pH and the ionic strength of the binding buffer and by temperature, indicating the involvement of both electrostatic and hydrophobic interactions. Binding kinetics and binding capacity were similar for membranes of the MM-Cf0 and MM-Cf9 genotypes. In all solanaceous plant species tested, an AVR9 binding site was present, whereas in the nonsolanaceous species that were analyzed, such a binding site could not be identified. The ability of membranes isolated from different solanaceous plant species to bind AVR9 seems to correlate with the presence of members of the Cf-9 gene family, but whether this correlation is functional remains to be determined.     

Salicylic acid is not required for Cf-2- and Cf-9-dependent resistance of tomato to Cladosporium fulvum

Tomato leaves or cotyledons expressing the Cf-2 or Cf-9 Cladosporium fulvum resistance genes induce salicylic acid (SA) synthesis following infiltration with intercellular washing fluid (IF) containing the fungal peptide elicitors Avr2 and Avr9. We investigated whether SA was required for Cf gene-dependent resistance. Tomato plants expressing the bacterial gene nahG, encoding salicylate hydroxylase, did not accumulate SA in response to IF infiltration but remained fully resistant to C. fulvum. NahG Cf0 plants were as susceptible to C. fulvum as wild-type Cf0. Neither free nor conjugated salicylic acid accumulated in IF-infiltrated Cf2 and Cf9 NahG leaves and cotyledons but conjugated catechol did accumulate. The Cf-9-dependent necrotic response to IF was prevented in NahG plants and replaced by a chlorotic Cf-2-like response. SA also potentiated Cf-9-mediated necrosis in IF-infiltrated wild-type leaves. In contrast, the Cf-2-dependent IF response was retained in NahG leaves and chlorosis was more pronounced than in the wild-type. The distribution of cell death between different cell types was altered in both Cf2 and Cf9 NahG leaves after IF injection. IF-induced accumulation of three SA-inducible defence-related genes was delayed and reduced but not abolished in NahG Cf2 and Cf9 leaves and cotyledons. NahG Tm-22 tomato showed increased hypersensitive response (HR) lesion size upon TMV infection, as observed in TMV-inoculated N gene-containing NahG tobacco plants.     

Cladosporium fulvum Avr4 protects fungal cell walls against hydrolysis by plant chitinases accumulating during infection

Resistance against the leaf mold fungus Cladosporium fulvum is mediated by the tomato Cf proteins which belong to the class of receptor-like proteins and indirectly recognize extracellular avirulence proteins (Avrs) of the fungus. Apart from triggering disease resistance, Avrs are believed to play a role in pathogenicity or virulence of C. fulvum. Here, we report on the avirulence protein Avr4, which is a chitin-binding lectin containing an invertebrate chitin-binding domain (CBM14). This domain is found in many eukaryotes, but has not yet been described in fungal or plant genomes. We found that interaction of Avr4 with chitin is specific, because it does not interact with other cell wall polysaccharides. Avr4 binds to chitin oligomers with a minimal length of three N-acetyl glucosamine residues. In vitro, Avr4 protects chitin against hydrolysis by plant chitinases. Avr4 also binds to chitin in cell walls of the fungi Trichoderma viride and Fusarium solani f. sp. phaseoli and protects these fungi against normally deleterious concentrations of plant chitinases. In situ fluorescence studies showed that Avr4 also binds to cell walls of C. fulvum during infection of tomato, where it most likely protects the fungus against tomato chitinases, suggesting that Avr4 is a counter-defensive virulence factor.     

The hydrophobin HCf-1 of Cladosporium fulvum is required for efficient water-mediated dispersal of conidia

Six hydrophobin genes (HCf-1 to -6) have thus far been identified in the tomato pathogen Cladosporium fulvum. HCf-1 to -4 are Class I hydrophobins and HCf-5 and -6 are Class II hydrophobins. In this paper we describe the isolation of deletion mutants that lack HCf-1, HCf-2, or both these genes. Global down-regulation of the expression of Class I hydrophobins is achieved by homology-dependent gene silencing. Analysis of the mutant strains shows that HCf-1 confers hydrophilic character to the conidia and this facilitates the dissemination of conidia on the surface of water droplets. Other Class I hydrophobins, such as HCf-3 or HCf-4, may be involved in the development and germination of conidia.     

The Cf-4 and Cf-9 resistance genes against Cladosporium fulvum are conserved in wild tomato species

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.