Fungal Pls1 tetraspanins as key factors of penetration into host plants: a role in re-establishing polarized growth in the appressorium?

The ability of plant pathogenic fungi to infect their host depends on successful penetration into plant tissues. This process often involves the differentiation of a specialized cell, the appressorium. Signalling pathways required for appressorium formation are conserved among fungi. However, the functions involved in appressorium maturation and penetration peg formation are still poorly understood. Recent studies have shown that Pls1 tetraspanins control an appressorial function required for penetration into host plants and are likely conserved among plant pathogenic fungi. Tetraspanins are small membrane proteins widely distributed among ascomycetes and basidiomycetes defining two distinct families; Pls1 tetraspanins are found in both ascomycetes and basidiomycetes and Tsp2 tetraspanins are specific to basidiomycetes. Both fungal tetraspanins families have similar secondary structures shared with animal tetraspanins. Pls1 tetraspanins are present as single genes in genomes of ascomycetes, allowing a unique opportunity to study their function in appressorium mediated penetration. Experimental evidence suggests that Pls1 tetraspanins are required for the formation of the penetration peg at the base of the appressorium, probably through re-establishing cell polarity.     

The tetraspanin gene ClPLS1 is essential for appressorium-mediated penetration of the fungal pathogen Colletotrichum lindemuthianum

Conservation of the molecular mechanisms controlling appressorium-mediated penetration during evolution was assessed through a functional study of the ClPLS1 gene from Colletotrichum lindemuthianum orthologous to the MgPLS1 from Magnaporthe grisea, involved in penetration peg development. These two plant-pathogenic Pyrenomycetes differentiate appressoria to penetrate into plant tissues. We showed that ClPLS1 is a functional homologue of MgPLS1 in M. grisea. Loss of ClPLS1 function had no effect on vegetative growth, conidiation or on appressorium differentiation and maturation. However, Clpls1::hph mutants are non-pathogenic on either intact or wounded bean leaves, as a result of a defect in the formation and/or positioning of the penetration pore and consequently in the formation of the penetration peg. These observations suggest that the fungal tetraspanins control a conserved appressorial function that could be required for the correct localization of the site where the penetration peg emerges.     

The Colletotrichum lagenarium MAP kinase gene CMK1 regulates diverse aspects of fungal pathogenesis

The infection process of Colletotrichum lagenarium, the causal agent of cucumber anthracnose disease, involves several key steps: germination; formation of melanized appressoria; appressorial penetration; and subsequent invasive growth in host plants. Here we report that the C. lagenarium CMK1 gene encoding a mitogen-activated protein (MAP) kinase plays a central role in these infection steps. CMK1 can complement appressorium formation of the Pmk1 MAP kinase mutant of Magnaporthe grisea. Deletion of CMK1 causes reduction of conidiation and complete lack of pathogenicity to the host plant. Surprisingly, in contrast to M. grisea pmk1 mutants, conidia of cmk1 mutants fail to germinate on both host plant and glass surfaces, demonstrating that the CMK1 MAP kinase regulates conidial germination. However, addition of yeast extract rescues germination, indicating the presence of a CMK1-independent pathway for regulation of conidial germination. Germinating conidia of cmk1 mutants fail to form appressoria and the mutants are unable to grow invasively in the host plant. This strongly suggests that MAP kinase signaling pathways have general significance for infection structure formation and pathogenic growth in phytopathogenic fungi. Furthermore, three melanin genes show no or slight expression in the cmk1 mutant when conidia fail to germinate, suggesting that CMK1 plays a role in gene expression required for appressorial melanization.     

Multiple contributions of peroxisomal metabolic function to fungal pathogenicity in Colletotrichum lagenarium

In Colletotrichum lagenarium, which is the causal agent of cucumber anthracnose, PEX6 is required for peroxisome biogenesis and appressorium-mediated infection. To verify the roles of peroxisome-associated metabolism in fungal pathogenicity, we isolated and functionally characterized ICL1 of C. lagenarium, which encodes isocitrate lyase involved in the glyoxylate cycle in peroxisomes. The icl1 mutants failed to utilize fatty acids and acetate for growth. Although Icl1 has no typical peroxisomal targeting signals, expression analysis of the GFP-Icl1 fusion protein indicated that Icl1 localizes in peroxisomes. These results indicate that the glyoxylate cycle that occurs inside the peroxisome is required for fatty acid and acetate metabolism for growth. Importantly, in contrast with the pex6 mutants that form nonmelanized appressoria, the icl1 mutants formed appressoria that were highly pigmented with melanin, suggesting that the glyoxylate cycle is not essential for melanin biosynthesis in appressoria. However, the icl1 mutants exhibited a severe reduction in virulence. Appressoria of the icl1 mutants failed to develop penetration hyphae in the host plant, suggesting that ICL1 is involved in host invasion. The addition of glucose partially restored virulence of the icl1 mutant. Heat shock treatment of the host plant also enabled the icl1 mutants to develop lesions, implying that the infection defect of the icl1 mutant is associated with plant defense. Together with the requirement of PEX6 for appressorial melanization, our findings suggest that peroxisomal metabolic pathways play functional roles in appressorial melanization and subsequent host invasion steps, and the latter step requires the glyoxylate cycle.     

Polymorphic change of appressoria by the tomato powdery mildew Oidium neolycopersici on host tomato leaves reflects multiple unsuccessful penetration attempts

The appressorial shapes of the powdery mildews are an important clue to the taxonomy of the powdery mildew fungi, but the conidia of the tomato powdery mildew Oidium neolycopersici KTP-01 develop non-lobed, nipple-shaped, and moderately lobed or multilobed appressoria on the same leaves. To remove this ambiguity, we performed consecutive observations of sequential appressorial development of KTP-01 conidia with a high-fidelity digital microscope. Highly germinative conidia of KTP-01, collected from conidial pseudochains formed on the tomato leaves, were inoculated into host tomato and nonhost barley leaves or an artificial hydrophobic membrane (Parafilm). Events from germination initiation to appressorium formation were synchronous in all conidia on all materials used for inoculation, but post-appressorial behaviors varied among the materials. Appressoria on the membrane-stuck glass slide formed several projections at different portions of the appressoria to repeat unsuccessful penetration attempts. Similar unsuccessful penetration behavior by KTP-01 conidia was observed in the inoculations into leaves of barley plants, wild tomato species Lycopersicon peruvianum LA2172 (carrying the Ol-4 gene for powdery mildew resistance), and a susceptible host tomato (Lycopersicon esculentum) that had been inoculated with the barley powdery mildew (Blumeria graminis f. sp. hordei, race 1) conidia. On the barley leaves, all penetrations of KTP-01 were impeded by the papillae formed beneath the sites of the appressorial projections. On both the wild tomato and the race 1-inoculated cultivated tomato plants, KTP-01 conidia were prevented from forming functional haustoria by hypersensitive epidermal cell death; this hypersensitive reaction involved the Ol-4 gene in the wild tomato plants or the 'induced resistance' acquired by the nonpathogenic conidia previously inoculated into the cultivated tomato plants. All these KTP-01 conidia produced several projections on the appressoria during the repeated unsuccessful penetration attempts and eventually exhibited multilobed appressoria. On the host tomato leaves inoculated singly with KTP-01 conidia, fewer than 20% of the conidia located appressoria on the central part of target epidermal cells and succeeded in forming functional haustoria at the first penetration attempt without forming an appressorial projection. These conidia exhibited non-lobed appressoria. The remaining conidia, however, whose appressoria were located on/near the border of the target epidermal cells, were more likely to fail to penetrate at the first penetration, and then to develop additional projections for subsequent penetrations. Most conidia succeeded in forming functional haustoria at the second to fourth penetration attempts, but a few conidia failed to produce haustoria at all attempted penetrations. Eventually, the conidia that succeeded at the second penetration possessed a single appressorial projection (exhibiting the nipple-shaped appressoria), whereas the remaining conidia exhibited moderately lobed appressoria with two to four appressorial projections and multilobed appressoria, with more projections. Thus, the present study revealed that the basic shape of appressoria of KTP-01 was the non-lobed type, and that polymorphic changes of the appressoria occurred as a result of successive production of projections during repeated unsuccessful penetration attempts.     

Melanization of appressoria is critical for the pathogenicity of <Emphasis Type="Italic">Diplocarpon rosae</Emphasis>

Previous studies have shown the role of melanized appressoria in the pathogenicity of various fungi. Diplocarpon rosae is a worldwide outdoor fungal pathogen of rose plants causing black spot disease of rose leaves. To fully understand how this fungus colonizes its host, which is critical for the development of an efficient and sustainable disease management program, we studied the fungal (especially the appressoria) structures of D. rosae in detail at an early stage of infection. Using both microscopic and biochemical analyses, we observed strong melanized appressoria formation localized at the point of D. rosae penetration, which forms the pathogen–plant interface. Treatment of infected plants with melanin biosynthesis inhibitors (MBIs) prevented melanization of D. rosae appressoria and positively correlated with significant reductions in black spot disease symptoms, suggesting that melanization of appressoria might be a critical factor for the pathogenicity of D. rosae. Our findings were confirmed and validated by the lack of melanized appressorial ring formation on an artificial surface and on a D. rosae-non host plant system, Arabidopsis thaliana. Our findings suggest that localized melanization of appressoria is a crucial factor for the pathogenicity of D. rosae and treatment of the fungus with MBIs seems to be a promising disease management alternative for black spot disease of roses.     

A new class of tetraspanins in fungi

Tetraspanins are animal proteins involved in membrane complexes that are involved in cell adhesion, differentiation, and motility. The PLS1 gene from rice blast fungus Magnaporthe grisea encodes a protein (Pls1p) structurally related to tetraspanins that is required for pathogenicity. In Botrytis cinerea public sequences, we identified an EST homologous to PLS1. Using degenerated oligonucleotides, we amplified sequences homologous to PLS1 in fungi Colletotrichum lindemuthianum and Neurospora crassa. Analysis of N. crassa and M. grisea genome sequences revealed the presence of a single tetraspanin gene. Thus, fungi differ from animals, which contain between 20 and 37 paralogous tetraspanin genes. Fungal proteins encoded by BcPLS1, ClPLS1, and NcPLS1 display all the structural hallmarks of tetraspanins (predicted topology with four transmembrane domains, extra- and intracellular loops; conserved cysteine-based patterns in second extracellular loop). Phylogenetic analysis suggests that these genes define a new family of orthologous genes encoding fungal-specific tetraspanins.     

Primary and secondary metabolism regulates lipolysis in appressoria of Colletotrichum orbiculare

The conidia of Colletotrichum orbiculare, the causal agent of cucumber anthracnose, develop appressoria that are pigmented with melanin for host plant infection. Premature appressoria contain abundant lipid droplets (LDs), but these disappear during appressorial maturation, indicating lipolysis inside the appressorial cells. The lipolysis and melanization in appressoria require the peroxin PEX6, suggesting the importance of peroxisomal metabolism in these processes. To investigate the relationships between appressorial lipolysis and fungal metabolic pathways, C. orbiculare knockout mutants of MFE1, which encodes a peroxisomal multifunctional enzyme, were generated in this study, and the phenotype of the mfe1 mutants was investigated. In contrast to the wild-type strain, which forms melanized appressoria, the mfe1 mutants formed colorless nonmelanized appressoria with abundant LDs, similar to those of pex6 mutants. This indicates that fatty acid β-oxidation in peroxisomes is critical for the appressorial melanization and lipolysis of C. orbiculare. Soraphen A, a specific inhibitor of acetyl-CoA carboxylase, inhibited appressorial lipolysis and melanization, producing phenocopies of the mfe1 mutants. This suggests that the conversion of acetyl-CoA, derived from fatty acid β-oxidation, to malonyl-CoA is required for the activation of lipolysis in appressoria. Surprisingly, we found that genetically blocking PKS1-dependent polyketide synthesis, an initial step in melanin biosynthesis, also impaired appressorial lipolysis. In contrast, genetically or pharmacologically blocking the steps in melanin synthesis downstream from PKS1 did not abolish appressorial lipolysis. These findings indicate that melanin biosynthesis, as well as fatty acid β-oxidation, is involved in the regulation of lipolysis inside fungal infection structures.     

Independent genetic mechanisms mediate turgor generation and penetration peg formation during plant infection in the rice blast fungus

The first barrier to infection encountered by foliar pathogens is the host cuticle. To traverse this obstacle, many fungi produce specialized infection cells called appressoria. MST12 is essential for appressorium-mediated penetration and infectious growth by the rice pathogen Magnaporthe grisea. In this study, we have characterized in detail the penetration defects of an mst12 deletion mutant. Appressoria formed by the mst12 mutant developed normal turgor pressure and ultrastructure but failed to form penetration pegs either on cellophane membranes or on plant epidermal cells. Deletion and site-directed mutagenesis analyses indicated that both the homeodomain and zinc finger domains, but not the middle region, of MST12 are essential for appressorial penetration and plant infection. The mst12 mutant appeared to be defective in microtubule reorganization associated with penetration peg formation. In mature appressoria, the mutant lacked vertical microtubules observed in the wild type. The mst12 mutant also failed to elicit localized host defence responses, including papilla formation and autofluorescence. Our data indicate that generation of appressorium turgor pressure and formation of the penetration peg are two independent processes. MST12 may play important roles in regulating penetration peg formation and directing the physical forces exerted by the appressorium turgor in mature appressoria.     

Multiple Contributions of Peroxisomal Metabolic Function to Fungal Pathogenicity in Colletotrichum lagenarium

In Colletotrichum lagenarium, which is the causal agent of cucumber anthracnose, PEX6 is required for peroxisome biogenesis and appressorium-mediated infection. To verify the roles of peroxisome-associated metabolism in fungal pathogenicity, we isolated and functionally characterized ICL1 of C. lagenarium, which encodes isocitrate lyase involved in the glyoxylate cycle in peroxisomes. The icl1 mutants failed to utilize fatty acids and acetate for growth. Although Icl1 has no typical peroxisomal targeting signals, expression analysis of the GFP-Icl1 fusion protein indicated that Icl1 localizes in peroxisomes. These results indicate that the glyoxylate cycle that occurs inside the peroxisome is required for fatty acid and acetate metabolism for growth. Importantly, in contrast with the pex6 mutants that form nonmelanized appressoria, the icl1 mutants formed appressoria that were highly pigmented with melanin, suggesting that the glyoxylate cycle is not essential for melanin biosynthesis in appressoria. However, the icl1 mutants exhibited a severe reduction in virulence. Appressoria of the icl1 mutants failed to develop penetration hyphae in the host plant, suggesting that ICL1 is involved in host invasion. The addition of glucose partially restored virulence of the icl1 mutant. Heat shock treatment of the host plant also enabled the icl1 mutants to develop lesions, implying that the infection defect of the icl1 mutant is associated with plant defense. Together with the requirement of PEX6 for appressorial melanization, our findings suggest that peroxisomal metabolic pathways play functional roles in appressorial melanization and subsequent host invasion steps, and the latter step requires the glyoxylate cycle.     

Licensed to kill: the lifestyle of a necrotrophic plant pathogen

Necrotrophic plant pathogens have received an increasing amount of attention over the past decade. Initially considered to invade their hosts in a rather unsophisticated manner, necrotrophs are now known to use subtle mechanisms to subdue host plants. The gray mould pathogen Botrytis cinerea is one of the most comprehensively studied necrotrophic fungal plant pathogens. The genome sequences of two strains have been determined. Targeted mutagenesis studies are unraveling the roles played in the infection process by a variety of B. cinerea genes that are required for penetration, host cell killing, plant tissue decomposition or signaling. Our increasing understanding of the tools used by a necrotrophic fungal pathogen to invade plants will be instrumental to designing rational strategies for disease control.     

Two novel fungal virulence genes specifically expressed in appressoria of the rice blast fungus

The PMK1 mitogen-activated protein kinase gene regulates appressorium formation and infectious hyphae growth in the rice blast fungus. To further characterize this mitogen-activated protein kinase pathway, we constructed a subtraction library enriched for genes regulated by PMK1. Two genes identified in this library, GAS1 and GAS2, encode small proteins that are homologous with gEgh16 of the powdery mildew fungus. Both were expressed specifically during appressorium formation in the wild-type strains, but neither was expressed in the pmk1 mutant. Mutants deleted in GAS1 and GAS2 had no defect in vegetative growth, conidiation, or appressoria formation, but they were reduced in appressorial penetration and lesion development. Interestingly, deletion of both GAS1 and GAS2 did not have an additive effect on appressorial penetration and lesion formation. The GAS1-green fluorescent protein and GAS2-green fluorescent protein fusion proteins were expressed only in appressoria and localized in the cytoplasm. These two genes may belong to a class of proteins specific for filamentous fungi and function as novel virulence factors in fungal pathogens.     

Fungicide activity through activation of a fungal signalling pathway

Fungicides generally inhibit enzymatic reactions involved in fungal cellular biosynthesis. Here we report, for the first time, an example of fungicidal effects through hyperactivation of a fungal signal transduction pathway. The OSC1 gene, encoding a MAP kinase (MAPK) related to yeast Hog1, was isolated from the fungal pathogen Colletotrichum lagenarium that causes cucumber anthracnose. The osc1 knockout mutants were sensitive to high osmotic stress and showed increased resistance to the fungicide fludioxonil, indicating that Osc1 is involved in responses to hyperosmotic stress and sensitivity to fludioxonil. The Osc1 MAPK is phosphorylated under high osmotic conditions, indicating activation of Osc1 by high osmotic stress. Importantly, fludioxonil treatment also activates phosphorylation of Osc1, suggesting that improper activation of Osc1 by fludioxonil has negative effects on fungal growth. In the presence of fludioxonil, the wild-type fungus was not able to infect the host plant because of a failure of appressorium-mediated penetration, whereas osc1 mutants successfully infected plants. Analysis using a OSC1-GFP fusion gene indicated that Osc1 is rapidly translocated to the nucleus in appressorial cells after the addition of fludioxonil, suggesting that fludioxonil impairs the function of infection structures by activation of Osc1. Furthermore, fludioxonil activates Hog1-type MAPKs in the plant pathogenic fungi Cochliobolus heterostrophus and Botrytis cinerea. These results strongly suggest that fludioxonil acts as a fungicide, in part, through activation of the MAPK cascade in fungal pathogens.     

Gene identification in the obligate fungal pathogen Blumeria graminis by expressed sequence tag analysis

Powdery mildew of barley is caused by the obligate fungal pathogen Blumeria graminis f. sp. hordei. Haploid conidia of B. graminis, landing on the barley leaf, germinate to form first a primary germ tube and then an appressorial germ tube. The appressorial germ tube differentiates into a mature appressorium from which direct penetration of host epidermis occurs. Here we present data on 4908 expressed sequence tags obtained from B. graminis conidia. The combined sequences represent 2676 clones describing 1669 individual genes. Comparison with sequences from other pathogenic and nonpathogenic fungi defines hypotheses on the genes required for pathogenicity and growth on the host. The putative roles of some of the identified genes are discussed.     

GPI7-mediated glycosylphosphatidylinositol anchoring regulates appressorial penetration and immune evasion during infection of Magnaporthe oryzae

Glycosylphosphatidylinositol (GPI) anchoring plays key roles in many biological processes by targeting proteins to the cell wall; however, its roles are largely unknown in plant pathogenic fungi. Here, we reveal the roles of the GPI anchoring in Magnaporthe oryzae during plant infection. The GPI-anchored proteins were found to highly accumulate in appressoria and invasive hyphae. Disruption of GPI7, a GPI anchor-pathway gene, led to a significant reduction in virulence. The Δgpi7 mutant showed significant defects in penetration and invasive growth. This mutant also displayed defects of the cell wall architecture, suggesting GPI7 is required for cell wall biogenesis. Removal of GPI-anchored proteins in the wild-type strain by hydrofluoric acid (HF) pyridine treatment exposed both the chitin and β-1,3-glucans to the host immune system. Exposure of the chitin and β-1,3-glucans was also observed in the Δgpi7 mutant, indicating GPI-anchored proteins are required for immune evasion. The GPI anchoring can regulate subcellular localization of the Gel proteins in the cell wall for appressorial penetration and abundance of which for invasive growth. Our results indicate the GPI anchoring facilitates the penetration of M. oryzae into host cells by affecting the cell wall integrity and the evasion of host immune recognition.     

A putative MAP kinase kinase kinase, MCK1, is required for cell wall integrity and pathogenicity of the rice blast fungus, Magnaporthe oryzae

Insertional mutagenesis of Magnaporthe oryzae led to the identification of MCK1, a pathogenicity gene predicted to encode mitogen-activated protein kinase kinase kinase (MAPKKK) homologous to BCK1 in Saccharomyces cerevisiae. Targeted disruption of MCK1 resulted in the fungus undergoing autolysis and showing hypersensitivity to cell-wall-degrading enzyme. The mck1 produced significantly reduced numbers of conidia and developed appressoria in a slightly retarded manner compared with the wild type. Appressorium of the mck1 mutant was unable to penetrate into plant tissues, thereby rendering the mutant nonpathogenic. Cytorrhysis assay and monitoring of lipid mobilization suggested that the appressorial wall was altered, presumably affecting the level of turgor pressure within appressorium. Furthermore, the mck1 mutant failed to grow inside plant tissue. Complementation of the mutated gene restored its ability to cause disease symptoms, demonstrating that MCK1 is required for fungal pathogenicity. Taken together, our results suggest that MCK1 is an MAPKKK involved in maintaining cell wall integrity of M. oryzae, and that remodeling of the cell wall in response to host environments is essential for fungal pathogenesis.     

A gene involved in modifying transfer RNA is required for fungal pathogenicity and stress tolerance of Colletotrichum lagenarium

7-Methylguanosine (m7G) modification of tRNA occurs widely in prokaryotes and eukaryotes, although information about its biological roles is limited. Here, we report that a gene involved in m7G modification of tRNA is required for infection by the phytopathogenic fungus Colletotrichum lagenarium. Analysis of the infection-deficient mutant of C. lagenarium, produced by plasmid insertional mutagenesis, identified a tagged gene that is designated APH1. The aph1 mutants, generated by targeted gene disruption, exhibit significant reduction in pathogenicity on the host plants. We conclude that APH1 is required for fungal infection in C. lagenarium. Aph1 showed a strong similarity to Saccharomyces cerevisiae Trm8 involved in m7G modification of tRNA. The m7G content of tRNA from the aph1 deletion mutant was severely reduced compared with that from the wild type, indicating that APH1 is required for m7G methyltransferase activity. Appressoria formed by the aph1 mutants developed penetration hyphae into cellophane, suggesting that appressoria of the mutants retain basic function for penetration. However, the aph1 mutants failed to develop intracellular penetration hyphae into epidermis of the host plants, suggesting a specific requirement of APH1 for appressorium-mediated host invasion. The mutants also had increased sensitivity to salinity and H2O2 stresses. Interestingly, a heat shock treatment on the host plants enabled the aph1 mutant to penetrate them. These data suggest that the APH1 is required for the plant invasion, probably to overcome environmental stresses derived from basal preinvasion (penetration) defence of the host plants.     

A pattern recognition tool for quantitative analysis of in planta hyphal growth of powdery mildew fungi

The development of fungal pathogens can be quantified easily at the level of spore germination or penetration. However, the exact quantification of hyphal growth rates after initial, successful host invasion is much more difficult. Here, we report on the development of a new pattern recognition software (HyphArea) for automated quantitative analysis of hyphal growth rates of powdery mildew fungi on plant surfaces that usually represent highly irregular and noisy image backgrounds. By using HyphArea, we measured growth rates of colonies of the barley powdery mildew, Blumeria graminis f. sp. hordei, on susceptible and induced-resistant host plants. Hyphal growth was not influenced by the resistance state of the plants up to 48 h postinoculation. At later time points, growth rate increased on susceptible plants, whereas it remained restricted on induced-resistant plants. This difference in hyphal growth rate was accompanied by lack of secondary haustoria formation on induced-resistant plants, suggesting that induced resistance in barley against Blumeria graminis is caused mainly by reduced penetration rates of primary as well as secondary appressoria leading, finally, to fewer and less-developed fungal colonies. No evidence was found for reduced nutrient-uptake efficiency of the primary haustoria in induced-resistant leaves, which would be expected to have resulted in reduced hyphal growth rates during the first 48 h of the interaction.