<Emphasis Type="Italic">HvCEBiP</Emphasis>, a gene homologous to rice chitin receptor <Emphasis Type="Italic">CEBiP</Emphasis>, contributes to basal resistance of barley to <Emphasis Type="Italic">Magnaporthe oryzae</Emphasis>

Background  

Rice CEBiP recognizes chitin oligosaccharides on the fungal cell surface or released into the plant apoplast, leading to the expression of plant disease resistance against fungal infection. However, it has not yet been reported whether CEBiP is actually required for restricting the growth of fungal pathogens. Here we evaluated the involvement of a putative chitin receptor gene in the basal resistance of barley to the ssd1 mutant of Magnaporthe oryzae, which induces multiple host defense responses.     

Microscopy and proteomic analysis of the non-host resistance of <Emphasis Type="Italic">Oryza sativa</Emphasis> to the wheat leaf rust fungus, <Emphasis Type="Italic">Puccinia triticina</Emphasis> f. sp. <Emphasis Type="Italic">tritici</Emphasis>

Rice (Oryza sativa) cv. Nipponbare expresses non-host resistance (NHR) to the wheat leaf rust fungus, Puccinia triticina f. sp. tritici (Ptt). When the leaves of cv. Nipponbare were inoculated with Ptt, approx 93% of the urediniospores germinated on the leaf surface, but only 10% of the germinated spores formed appressoria over the stomata at one day post inoculation (1 dpi). Hydrogen peroxide (H₂O₂) accumulated in host cells around the appressoria at 3 dpi. Approx. 3% of the appressoria produced short hyphae inside the leaf, and fluorescence was observed in tissue invaded by the hyphae by 7 dpi. At 22 dpi, 0.2% of the sites with appressoria formed branching infection hypha in mesophyll cells, but no substomatal vesicles, haustorial mother cells or haustoria were observed. Proteins were extracted from leaves 3 dpi and analyzed by two-dimensional gel electrophoresis (2-DE). A total 33 spots were reproducibly up-regulated and 9 were down-regulated by infection compared to the water inoculated control. Of these, 30 were identified by MALDI-TOF Mass Spectrometry. The identified proteins participate in defense/stress responses, energy/carbohydrate metabolism, oxidation–reduction processes, protein folding/turnover/cleavage/degradation, signal transduction and cell death regulation. The results indicates that NHR of rice to Ptt is consistent with a shift in protein and energy metabolism, increased antimicrobial activities, possibly including phytoalexin accumulation and cell wall reinforcement, increased cell repair, antioxidive and detoxification reactions, and enhanced prevention of plant cell death. Nearly half of the up-regulated identified proteins were associated with chloroplast and mitochondrial physiology suggesting important roles for these organelles during NHR.     

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.     

Transcriptome analysis reveals new insight into appressorium formation and function in the rice blast fungus <Emphasis Type="Italic">Magnaporthe oryzae</Emphasis>

Background  

Rice blast disease is caused by the filamentous Ascomycetous fungus Magnaporthe oryzae and results in significant annual rice yield losses worldwide. Infection by this and many other fungal plant pathogens requires the development of a specialized infection cell called an appressorium. The molecular processes regulating appressorium formation are incompletely understood.     

ATG7 contributes to plant basal immunity towards fungal infection

Autophagy has an important function in cellular homeostasis. In recent years autophagy has been implicated in plant basal immunity and assigned negative (“anti-death”) and positive (“pro-death”) regulatory functions in controlling cell death programs that establish sufficient immunity to microbial infection. We recently showed that Arabidopsis mutants lacking the autophagy-associated (ATG) genes ATG5, ATG10 and ATG18a are compromised in their resistance towards infection with necrotrophic fungal pathogens but display an enhanced resistance towards biotrophic bacterial invaders. Thus, the function of autophagy as either being pro-death or anti-death depends critically on the lifestyle and infection strategy of invading microbes. Here we show that ATG7 contributes to resistance to fungal pathogens. Genetic inactivation of ATG7 results in elevated susceptibility towards the necrotrophic fungal pathogen, Alternaria brassicicola, with atg7 mutants developing spreading necrosis accompanied by production of reactive oxygen intermediates. Likewise, treatment with the fungal toxin fumonisin B1 causes spreading lesion formation in the atg7 mutant. We conclude that ATG7-dependent autophagy constitutes an “anti-death” (“pro-survival”) plant mechanism to control the containment of cell death and immunity to necrophic fungal infection.Key words: autophagy, ATG7, basal immunity, fungal resistance, arabidopsisPlants have evolved a bipartite plant immune system to cope with microbial infections. The first layer of defense relies on the recognition of pathogen-associated molecular patterns (PAMP) by pattern-recognition receptors (PAMP-triggered immunity, PTI).^1,2 To overcome this defense strategy, successful pathogens deliver so-called effector proteins into plant cells to modify host cellular processes and to suppress immune responses to enhance virulence. The presence or activities of these microbial effectors is sensed by plant resistance proteins and triggers the second layer of defense, the effector-triggered immunity (ETI).^1,2 In contrast to PTI, ETI is most often accompanied by programmed host cell death (PCD) at the site of attempted microbial invasion; however the molecular basis of this apoptosis-like hypersensitive response (HR) is largely unknown.In recent years evidence accumulated that a non-apoptotic form of cell death called autophagy is not only involved in animal PCD and innate immunity³ but is also an important component in the plant basal immune response.⁴ Generally, autophagy (auto, meaning “self” and phagy, “to eat”) is a cytoplasmic bulk degradation process in which cellular components are targeted to lysosomal or vacuolar degradation. This process is ubiquitous in eukaryotic organisms and is considered to aid cellular survival, differentiation, development and homeostasis by nutrient recycling or removal of damaged or toxic materials.^5–7     

Autophagy controls plant basal immunity in a pathogenic lifestyle-dependent manner

Plant genomes harbor autophagy-related (ATG) genes that encode major components of the eukaryotic autophagic machinery. Autophagy in plants has been functionally linked to senescence, oxidative stress adaptation and the nutrient starvation response. In addition, plant autophagy has been assigned negative (‘anti-death’) and positive (‘pro-death’) regulatory functions in controlling cell death programs that establish sufficient immunity to microbial infection. The role of autophagy in plant disease and basal immunity to microbial infection has, however, not been studied in detail. We have employed a series of autophagy-deficient genotypes of the genetic model plant Arabidopsis thaliana in various infection systems. Genotypes lacking ATG5, ATG10 or ATG18a develop spreading necrosis and enhanced disease susceptibility upon infection with toxin-producing pathogens preferring a necrotrophic lifestyle. These findings suggest that autophagy positively controls the containment of host tissue integrity upon infections by host-destructive microbes. In contrast, autophagy-deficient genotypes exhibit markedly increased immunity to infections by biotrophic pathogens through altered homeostasis of the plant hormone salicylic acid, thus suggesting an additional negative regulatory role of autophagy in plant basal immunity. In sum, our findings suggest that the role of plant autophagy in immunity cannot be generalized, and depends critically on the lifestyle and infection strategy of invading microbes.     

Glutamate synthase MoGlt1‐mediated glutamate homeostasis is important for autophagy,virulence and conidiation in the rice blast fungus

Glutamate homeostasis plays a vital role in central nitrogen metabolism and coordinates several key metabolic functions. However, its function in fungal pathogenesis and development has not been investigated in detail. In this study, we identified and characterized a glutamate synthase gene MoGLT1 in the rice blast fungus Magnaporthe oryzae that was important to glutamate homeostasis. MoGLT1 was constitutively expressed, but showed the highest expression level in appressoria. Deletion of MoGLT1 resulted in a significant reduction in conidiation and virulence. The ΔMoglt1 mutants were defective in appressorial penetration and the differentiation and spread of invasive hyphae in penetrated plant cells. The addition of exogenous glutamic acid partially rescued the defects of the ΔMoglt1 mutants in conidiation and plant infection. Assays for MoAtg8 expression and localization showed that the ΔMoglt1 mutants were defective in autophagy. The ΔMoglt1 mutants were delayed in the mobilization of glycogens and lipid bodies from conidia to developing appressoria. Taken together, our results show that glutamate synthase MoGlt1‐mediated glutamate homeostasis is important for pathogenesis and development in the rice blast fungus, possibly via the regulation of autophagy.     

Calcium-mediated perception and defense responses activated in plant cells by metabolite mixtures secreted by the biocontrol fungus <Emphasis Type="Italic">Trichoderma atroviride</Emphasis>

Background  

Calcium is commonly involved as intracellular messenger in the transduction by plants of a wide range of biotic stimuli, including signals from pathogenic and symbiotic fungi. Trichoderma spp. are largely used in the biological control of plant diseases caused by fungal phytopathogens and are able to colonize plant roots. Early molecular events underlying their association with plants are relatively unknown.     

FoEG1, a secreted glycoside hydrolase family 12 protein from Fusarium oxysporum,triggers cell death and modulates plant immunity

Fusarium oxysporum is an important soilborne fungal pathogen with many different formae speciales that can colonize the plant vascular system and cause serious crop wilt disease worldwide. We found a glycoside hydrolase family 12 protein FoEG1, secreted by F. oxysporum, that acted as a pathogen-associated molecular pattern (PAMP) targeting the apoplast of plants to induce cell death. Purified FoEG1 protein triggered cell death in different plants and induced the plant defence response to enhance the disease resistance of plants. The ability of FoEG1 to induce cell death was mediated by leucine-rich repeat (LRR) receptor-like kinases BAK1 and SOBIR1, and this ability was independent of its hydrolase activity. The mutants of cysteine residues did not affect the ability of FoEG1 to induce cell death, and an 86 amino acid fragment from amino acid positions 144 to 229 of FoEG1 was sufficient to induce cell death in Nicotiana benthamiana. In addition, the expression of FoEG1 was strongly induced in the early stage of F. oxysporum infection of host plants, and FoEG1 deletion or loss of enzyme activity reduced the virulence of F. oxysporum. Therefore, our results suggest that FoEG1 can contribute to the virulence of F. oxysporum depending on its enzyme activity and can also act as a PAMP to induce plant defence responses.     

Sensing and adhesion are adaptive functions in the plant pathogenic xanthomonads

Background  

Bacterial plant pathogens belonging to the Xanthomonas genus are tightly adapted to their host plants and are not known to colonise other environments. The host range of each strain is usually restricted to a few host plant species. Bacterial strains responsible for the same type of symptoms on the same host range cluster in a pathovar. The phyllosphere is a highly stressful environment, but it provides a selective habitat and a source of substrates for these bacteria. Xanthomonads colonise host phylloplane before entering leaf tissues and engaging in an invasive pathogenic phase. Hence, these bacteria are likely to have evolved strategies to adapt to life in this environment. We hypothesised that determinants responsible for bacterial host adaptation are expressed starting from the establishment of chemotactic attraction and adhesion on host tissue.     

Cytology of induced systemic resistance of cucumber to Colletotrichum lagenarium

The infection of cucumber leaves by Colletotrichum lagenarium was studied using cytological methods. Its progress in untreated plants was compared with that in plants in which systemic resistance had been induced by pre-infecting the first true leaf with the same fungus. In induced plants, a reduction of fungal development was observed at the leaf surface, in the epidermis, and in the mesophyll. On the leaf surface, formation of appressoria was slightly reduced. In the epidermis, enhanced formation of papillae beneath appressoria, and possibly increased lignification of entire cells, correlated with reduced development of infection hyphae. Papillae contained callose, identified by staining with aniline-blue fluorochrome and digestion with -1,3-glucanase, as a main structural component. In the mesophyll, reduced fungal development provided evidence for the existence of an additional induced defence reaction. The results imply that preinfection elicited a systemic, multicomponent defence reaction of the host plant against the fungus.Dedicated to the memory of Professor H. Grisebach     

The diverse roles of autophagy in medically important fungi

Autophagy is a highly conserved eukaryotic mechanism whereby cells recycle cellular elements to survive under adverse conditions. Surprisingly, of the three fungal pathogens of greatest relevance to human health, only Cryptococcus neoformans has been shown to require this process during infection. In contrast, autophagy is dispensable for the virulence of both Candida albicans and Aspergillus fumigatus. The divergent roles for autophagy in these opportunistic species underscore the uniqueness of the host infection niche occupied by each fungus and provide insights into the evolutionary pressures that may have influenced the need for autophagy during infection. Further study of fungal autophagy may reveal the host signals which induce this protective response and determine if these signals differ between host cells or tissues. In addition, a comprehensive understanding of the autophagy machinery in fungal pathogens may provide a rational basis for the design of future therapeutic interventions to improve outcome in patients who are at risk for these infections.     

A conserved GH17 glycosyl hydrolase from plant pathogenic Dothideomycetes releases a DAMP causing cell death in tomato

To facilitate infection, pathogens deploy a plethora of effectors to suppress basal host immunity induced by exogenous microbe-associated or endogenous damage-associated molecular patterns (DAMPs). In this study, we have characterized family 17 glycosyl hydrolases of the tomato pathogen Cladosporium fulvum (CfGH17) and studied their role in infection. Heterologous expression of CfGH17-1 to 5 by potato virus X in different tomato cultivars showed that CfGH17-1 and CfGH17-5 enzymes induce cell death in Cf-0, Cf-1 and Cf-5 but not in Cf-Ecp3 tomato cultivars or tobacco. Moreover, CfGH17-1 orthologues from other phytopathogens, including Dothistroma septosporum and Mycosphaerella fijiensis, also trigger cell death in tomato. CfGH17-1 and CfGH17-5 are predicted to be β-1,3-glucanases and their enzymatic activity is required for the induction of cell death. CfGH17-1 hydrolyses laminarin, a linear 1,3-β-glucan with 1,6-β linkages. CfGH17-1 expression is down-regulated during the biotrophic phase of infection and up-regulated during the necrotrophic phase. Deletion of CfGH17-1 in C. fulvum did not reduce virulence on tomato, while constitutive expression of CfGH17-1 decreased virulence, suggesting that abundant presence of CfGH17-1 during biotrophic growth may release a DAMP that activates plant defence responses. Under natural conditions CfGH17-1 is suggested to play a role during saprophytic growth when the fungus thrives on dead host tissue, which is in line with its high levels of expression at late stages of infection when host tissues have become necrotic. We suggest that CfGH17-1 releases a DAMP from the host cell wall that is recognized by a yet unknown host plant receptor.     

Rapid and dynamic subcellular reorganization following mechanical stimulation of <Emphasis Type="Italic">Arabidopsis</Emphasis>epidermal cells mimics responses to fungal and oomycete attack

Background  

Plant cells respond to the presence of potential fungal or oomycete pathogens by mounting a basal defence response that involves aggregation of cytoplasm, reorganization of cytoskeletal, endomembrane and other cell components and development of cell wall appositions beneath the infection site. This response is induced by non-adapted, avirulent and virulent pathogens alike, and in the majority of cases achieves penetration resistance against the microorganism on the plant surface. To explore the nature of signals that trigger this subcellular response and to determine the timing of its induction, we have monitored the reorganization of GFP-tagged actin, microtubules, endoplasmic reticulum (ER) and peroxisomes inArabidopsis plants – after touching the epidermal surface with a microneedle.     

<Emphasis Type="Italic">Coxiella burnetii</Emphasis> Nine Mile II proteins modulate gene expression of monocytic host cells during infection

Background  

Coxiella burnetii is an intracellular bacterial pathogen that causes acute and chronic disease in humans. Bacterial replication occurs within enlarged parasitophorous vacuoles (PV) of eukaryotic cells, the biogenesis and maintenance of which is dependent on C. burnetii protein synthesis. These observations suggest that C. burnetii actively subverts host cell processes, however little is known about the cellular biology mechanisms manipulated by the pathogen during infection. Here, we examined host cell gene expression changes specifically induced by C. burnetii proteins during infection.     

Identification and characterization of suppressors of plant cell death (SPD) effectors from Magnaporthe oryzae

Phytopathogenic microorganisms, including the fungal pathogen Magnaporthe oryzae, secrete a myriad of effector proteins to facilitate infection. Utilizing the transient expression of candidate effectors in the leaves of the model plant Nicotiana benthamiana, we identified 11 suppressors of plant cell death (SPD) effectors from M. oryzae that were able to block the host cell death reaction induced by Nep1. Ten of these 11 were also able to suppress BAX‐mediated plant cell death. Five of the 11 SPD genes have been identified previously as either essential for the pathogenicity of M. oryzae, secreted into the plant during disease development, or as suppressors or homologues of other characterized suppressors. In addition, of the remaining six, we showed that SPD8 (previously identified as BAS162) was localized to the rice cytoplasm in invaded and surrounding uninvaded cells during biotrophic invasion. Sequence analysis of the 11 SPD genes across 43 re‐sequenced M. oryzae genomes revealed that SPD2, SPD4 and SPD7 have nucleotide polymorphisms amongst the isolates. SPD4 exhibited the highest level of nucleotide diversity of any currently known effector from M. oryzae in addition to the presence/absence polymorphisms, suggesting that this gene is potentially undergoing selection to avoid recognition by the host. Taken together, we have identified a series of effectors, some of which were previously unknown or whose function was unknown, that probably act at different stages of the infection process and contribute to the virulence of M. oryzae.