Mycosphaerella graminicola

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Bruce A Mcdonald - One of the best experts on this subject based on the ideXlab platform.

  • association between virulence and triazole tolerance in the phytopathogenic fungus Mycosphaerella graminicola
    PLOS ONE, 2013
    Co-Authors: Lina Yang, Jiasui Zhan, Fangluan Gao, Liping Shang, Bruce A Mcdonald
    Abstract:

    Host resistance and synthetic antimicrobials such as fungicides are two of the main approaches used to control plant diseases in conventional agriculture. Although pathogens often evolve to overcome host resistance and antimicrobials, the majority of reports have involved qualitative host – pathogen interactions or antimicrobials targeting a single pathogen protein or metabolic pathway. Studies that consider jointly the evolution of virulence, defined as the degree of damage caused to a host by parasite infection, and antimicrobial resistance are rare. Here we compared virulence and fungicide tolerance in the fungal pathogen Mycosphaerella graminicola sampled from wheat fields across three continents and found a positive correlation between virulence and tolerance to a triazole fungicide. We also found that quantitative host resistance selected for higher pathogen virulence. The possible mechanisms responsible for these observations and their consequences for sustainable disease management are discussed.

  • Population genetic structure of Mycosphaerella graminicola and Quinone Outside Inhibitor (QoI) resistance in the Czech Republic
    European Journal of Plant Pathology, 2013
    Co-Authors: Jana Drabešová, Patrick Brunner, Pavel Ryšánek, Bruce A Mcdonald, Daniel Croll
    Abstract:

    Damage caused by the wheat pathogen Mycosphaerella graminicola increased rapidly during the last two decades in the Czech Republic. We collected isolates from naturally infected fields in seven wheat-growing locations and analysed these using eight microsatellite markers. All markers were highly polymorphic. We found a high degree of genetic diversity and low clonality within all sampled Czech populations. We identified 158 unique multilocus haplotypes among 184 isolates. Field populations showed weak genetic structure but we detected more differentiation between climatic regions within the Czech Republic. We compared the Czech field populations to populations from the United Kingdom, Germany and Switzerland and found a marked differentiation between Czech populations and Western European populations. We hypothesize that decades of different agricultural practices, including the use of different wheat cultivars, may explain this genetic differentiation. We detected a rapid increase in QoI fungicide resistance during the sampling period from 2005 to 2011, coinciding with the widespread application of this class of fungicides in the Czech Republic. M. graminicola populations in the Czech Republic underwent a rapid adaptive evolution from sensitivity to resistance similar to what was described earlier in Western Europe.

  • Zymoseptoria ardabiliae and Z. pseudotritici, two progenitor species of the septoria tritici leaf blotch fungus Z. tritici (synonym: Mycosphaerella graminicola)
    Mycologia, 2012
    Co-Authors: Eva H. Stukenbrock, W. Quaedvlieg, Mohammad Javan-nikhah, Marcello Zala, Pedro W. Crous, Bruce A Mcdonald
    Abstract:

    Zymoseptoria is a newly described genus that includes the prominent wheat pathogen Zymoseptoria tritici (synonyms Mycosphaerella graminicola and Septoria tritici). Studies indicated that the center of origin of Z. tritici is in the Middle East where this important pathogen emerged during the domestication of wheat. Several Zymoseptoria species have been found on uncultivated grasses in the Middle East, and in this article we describe two new Zymoseptoria species from Iran. These species, isolated from Elymus repens, Dactylis glomerata and Lolium perenne, are named Z. ardabiliae and Z. pseudotritici. Both species were identified by means of morphological characteristics and phylogenetic analyses of a seven-gene DNA dataset. These taxa comprise some of the closest known relatives of the wheat pathogen Z. tritici, confirming the reported close phylogenetic relationship between Z. tritici and Z. pseudotritici.

  • thermal adaptation in the fungal pathogen Mycosphaerella graminicola
    Molecular Ecology, 2011
    Co-Authors: Jiasui Zhan, Bruce A Mcdonald
    Abstract:

    Genetic differentiation in thermal adaptation can result from a trade-off between the performance of organisms across different temperatures or from the accumulation of deleterious mutations. In this experiment, we assayed thermal sensitivity of 138 genetically distinct Mycosphaerella graminicola isolates sampled from five host populations in four locations under two temperature regimes (22 and 15 °C) and found significant differences in growth rate and response to temperature among populations. On average, genetic differentiation accounted for more than 50% of phenotypic variation in thermal adaptation while plasticity contributed less than a quarter of phenotypic variation. Populations originating from warm places performed better under the high-temperature regime and had a larger positive response to increasing temperature. Pairwise population differentiation (Q(ST) ) in temperature sensitivity, measured by taking the ratio of growth rates at 22 to 15 °C, was positively and significantly correlated to the pairwise difference in annual mean temperature at the collection sites. Because overall Q(ST) in temperature sensitivity was significantly higher than overall G(ST) in neutral restriction fragment length polymorphism loci, we believe that the primary mechanism underlying this thermal adaptation is antagonistic pleiotropy. Our results indicate that temperature sensitivity is a better indicator of thermal adaptation than growth rate at individual temperatures.

  • intraspecific comparison and annotation of two complete mitochondrial genome sequences from the plant pathogenic fungus Mycosphaerella graminicola
    Fungal Genetics and Biology, 2008
    Co-Authors: Stefano F F Torriani, Stephen B Goodwin, Gert H. J. Kema, Jasmyn Pangilinan, Bruce A Mcdonald
    Abstract:

    The mitochondrial genomes of two isolates of the wheat pathogen Mycosphaerella graminicola were sequenced completely and compared to identify polymorphic regions. This organism is of interest because it is phylogenetically distant from other fungi with sequenced mitochondrial genomes and it has shown discordant patterns of nuclear and mitochondrial diversity. The mitochondrial genome of M. graminicola is a circular molecule of approximately 43,960bp containing the typical genes coding for 14 proteins related to oxidative phosphorylation, one RNA polymerase, two rRNA genes and a set of 27 tRNAs. The mitochondrial DNA of M. graminicola lacks the gene encoding the putative ribosomal protein (rps5-like), commonly found in fungal mitochondrial genomes. Most of the tRNA genes were clustered with a gene order conserved with many other ascomycetes. A sample of 35 additional strains representing the known global mt diversity was partially sequenced to measure overall mitochondrial variability within the species. Little variation was found, confirming previous RFLP-based findings of low mitochondrial diversity. The mitochondrial sequence of M. graminicola is the first reported from the family Mycosphaerellaceae or the order Capnodiales. The sequence also provides a tool to better understand the development of fungicide resistance and the conflicting pattern of high nuclear and low mitochondrial diversity in global populations of this fungus.

Gert H. J. Kema - One of the best experts on this subject based on the ideXlab platform.

  • the genomes of Mycosphaerella graminicola and m fijiensis
    Genomics of Plant-Associated Fungi: Monocot Pathogens, 2014
    Co-Authors: Stephen B Goodwin, Gert H. J. Kema
    Abstract:

    Mycosphaerella graminicola (synonym: Zymoseptoria tritici) and Mycosphaerella fijiensis in the Ascomycetes order Capnodiales are economically important pathogens causing Septoria tritici blotch of wheat and black Sigatoka or leaf streak of banana, respectively. Both diseases occur wherever their respective crops occur worldwide and have been difficult to control due to lack of effective resistance in the host plants and the development of fungicide insensitivity in populations of the pathogens. The 39.7-Mb genome of M. graminicola was sequenced completely and consists of 13 core chromosomes plus a dispensome of eight small chromosomes that differ from those in the core and probably originated by horizontal transfer from an unknown donor more than 10,000 years ago. The genome of M. fijiensis was much larger at 74.1 Mb, primarily due to proliferation of class I retrotransposons. It also may contain dispensable chromosomes that are different from those in M. graminicola. Both species contain a reduced set of genes for cell wall degrading enzymes compared to other plant-pathogenic fungi and possibly degrade proteins rather than carbohydrates during the biotrophic phase of infection. Interestingly, the genome of M. fijiensis contained effectors that are functionally similar to those seen in the related tomato pathogen, Cladosporium fulvum, and can be recognized by the corresponding tomato resistance genes. These effectors may be useful for future breeding of resistant banana cultivars and could help to identify sources of nonhost resistance from other crop species.

  • meiosis drives extraordinary genome plasticity in the haploid fungal plant pathogen Mycosphaerella graminicola
    PLOS ONE, 2009
    Co-Authors: Alexander H J Wittenberg, Gert H. J. Kema, Stephen B Goodwin, Theo Van Der Lee, Sarrah Ben Mbarek, S B Ware, Andrzej Kilian, Richard G F Visser, H J Schouten
    Abstract:

    Meiosis in the haploid plant-pathogenic fungus Mycosphaerella graminicola results in eight ascospores due to a mitotic division following the two meiotic divisions. The transient diploid phase allows for recombination among homologous chromosomes. However, some chromosomes of M. graminicola lack homologs and do not pair during meiosis. Because these chromosomes are not present universally in the genome of the organism they can be considered to be dispensable. To analyze the meiotic transmission of unequal chromosome numbers, two segregating populations were generated by crossing genetically unrelated parent isolates originating from Algeria and The Netherlands that had pathogenicity towards durum or bread wheat, respectively. Detailed genetic analyses of these progenies using high-density mapping (1793 DArT, 258 AFLP and 25 SSR markers) and graphical genotyping revealed that M. graminicola has up to eight dispensable chromosomes, the highest number reported in filamentous fungi. These chromosomes vary from 0.39 to 0.77 Mb in size, and represent up to 38% of the chromosomal complement. Chromosome numbers among progeny isolates varied widely, with some progeny missing up to three chromosomes, while other strains were disomic for one or more chromosomes. Between 15–20% of the progeny isolates lacked one or more chromosomes that were present in both parents. The two high-density maps showed no recombination of dispensable chromosomes and hence, their meiotic processing may require distributive disjunction, a phenomenon that is rarely observed in fungi. The maps also enabled the identification of individual twin isolates from a single ascus that shared the same missing or doubled chromosomes indicating that the chromosomal polymorphisms were mitotically stable and originated from nondisjunction during the second division and, less frequently, during the first division of fungal meiosis. High genome plasticity could be among the strategies enabling this versatile pathogen to quickly overcome adverse biotic and abiotic conditions in wheat fields.

  • phenotypic and genetic analysis of the triticum monococcum Mycosphaerella graminicola interaction
    New Phytologist, 2008
    Co-Authors: Hai-chun Jing, Gert H. J. Kema, D. J. Lovell, R. J. Gutteridge, Daniel Jenk, D. Kornyukhin, O. P. Mitrofanova, K E Hammondkosack
    Abstract:

    Here, the aim was to understand the cellular and genetic basis of the Triticum monococcum-Mycosphaerella graminicola interaction. Testing for 5 yr under UK field conditions revealed that all 24 T. monococcum accessions exposed to a high level of natural inocula were fully resistant to M. graminicola. When the accessions were individually inoculated in the glasshouse using an attached leaf seeding assay and nine previously characterized M. graminicola isolates, fungal sporulation was observed in only three of the 216 interactions examined. Microscopic analyses revealed that M. graminicola infection was arrested at four different stages post-stomatal entry. When the inoculated leaves were detached 30 d post inoculation and incubated at 100% humidity, abundant asexual sporulation occurred within 5 d in a further 61 interactions. An F2 mapping population generated from a cross between T. monococcum accession MDR002 (susceptible) and MDR043 (resistant) was inoculated with the M. graminicola isolate IPO323. Both resistance and in planta fungal growth were found to be controlled by a single genetic locus designated as TmStb1 which was linked to the microsatellite locus Xbarc174 on chromosome 7Am. Exploitation of T. monococcum may provide new sources of resistance to septoria tritici blotch disease.

  • intraspecific comparison and annotation of two complete mitochondrial genome sequences from the plant pathogenic fungus Mycosphaerella graminicola
    Fungal Genetics and Biology, 2008
    Co-Authors: Stefano F F Torriani, Stephen B Goodwin, Gert H. J. Kema, Jasmyn Pangilinan, Bruce A Mcdonald
    Abstract:

    The mitochondrial genomes of two isolates of the wheat pathogen Mycosphaerella graminicola were sequenced completely and compared to identify polymorphic regions. This organism is of interest because it is phylogenetically distant from other fungi with sequenced mitochondrial genomes and it has shown discordant patterns of nuclear and mitochondrial diversity. The mitochondrial genome of M. graminicola is a circular molecule of approximately 43,960bp containing the typical genes coding for 14 proteins related to oxidative phosphorylation, one RNA polymerase, two rRNA genes and a set of 27 tRNAs. The mitochondrial DNA of M. graminicola lacks the gene encoding the putative ribosomal protein (rps5-like), commonly found in fungal mitochondrial genomes. Most of the tRNA genes were clustered with a gene order conserved with many other ascomycetes. A sample of 35 additional strains representing the known global mt diversity was partially sequenced to measure overall mitochondrial variability within the species. Little variation was found, confirming previous RFLP-based findings of low mitochondrial diversity. The mitochondrial sequence of M. graminicola is the first reported from the family Mycosphaerellaceae or the order Capnodiales. The sequence also provides a tool to better understand the development of fungicide resistance and the conflicting pattern of high nuclear and low mitochondrial diversity in global populations of this fungus.

  • electrophoretic and cytological karyotyping of the foliar wheat pathogen Mycosphaerella graminicola reveals many chromosomes with a large size range
    Mycologia, 2007
    Co-Authors: Rahim Mehrabi, Masatoki Taga, Gert H. J. Kema
    Abstract:

    The karyotypes of three isolates of Mycosphaerella graminicola, the septoria tritici blotch pathogen of wheat, were analyzed with both pulsed field gel electrophoresis (PFGE) and the cytological technique called germ tube burst method (GTBM). These analyses revealed a chromosome length polymorphism among these isolates. The estimated genome size was 31-40 Mb depending on the isolates, indicating 17-22% redundancy in the genome of the standard strain IP0323 because such differences do not affect development, pathogenicity and sexual reproduction of the other isolates. The chromosome numbers in the three isolates were 18-20 and the chromosome size was 0.3-6 Mb. These data show that M. graminicola has the highest chromosome number and the smallest autosomes (A chromosomes) in filamentous ascomycetes. Our data also confirmed a large (> or =6 Mb) chromosome that was assembled recently in the IPO323 genome sequence. GTBM analyses revealed the mitotic metaphase chromosomes, enabling chromosome quantification, which was fully congruent with the PFGE analyses. These data will be instrumental in the final assembly of the M. graminicola genome.

B A Fraaije - One of the best experts on this subject based on the ideXlab platform.

  • update on mechanisms of azole resistance in Mycosphaerella graminicola and implications for future control
    Pest Management Science, 2013
    Co-Authors: H J Cools, B A Fraaije
    Abstract:

    This review summarises recent investigations into the molecular mechanisms responsible for the decline in sensitivity to azole (imidazole and triazole) fungicides in European populations of the Septoria leaf blotch pathogen, Mycosphaerella graminicola. The complex recent evolution of the azole target sterol 14a-demethylase (MgCYP51) enzyme in response to selection by the sequential introduction of progressively more effective azoles is described, and the contribution of individual MgCYP51 amino acid alterations and their combinations to azole resistance phenotypes and intrinsic enzyme activity is discussed. In addition, the recent identification of mechanisms independent of changes in MgCYP51 structure correlated with novel azole cross-resistant phenotypes suggests that the further evolution of M. graminicola under continued selection by azole fungicides could involve multiple mechanisms. The prospects for azole fungicides in controlling European M. graminicola populations in the future are discussed in the context of these new findings. Copyright (C) 2012 Society of Chemical Industry

  • update on mechanisms of azole resistance in Mycosphaerella graminicola and implications for future control
    Pest Management Science, 2013
    Co-Authors: H J Cools, B A Fraaije
    Abstract:

    This review summarises recent investigations into the molecular mechanisms responsible for the decline in sensitivity to azole (imidazole and triazole) fungicides in European populations of the Septoria leaf blotch pathogen, Mycosphaerella graminicola. The complex recent evolution of the azole target sterol 14α-demethylase (MgCYP51) enzyme in response to selection by the sequential introduction of progressively more effective azoles is described, and the contribution of individual MgCYP51 amino acid alterations and their combinations to azole resistance phenotypes and intrinsic enzyme activity is discussed. In addition, the recent identification of mechanisms independent of changes in MgCYP51 structure correlated with novel azole cross-resistant phenotypes suggests that the further evolution of M. graminicola under continued selection by azole fungicides could involve multiple mechanisms. The prospects for azole fungicides in controlling European M. graminicola populations in the future are discussed in the context of these new findings.

  • mechanism of binding of prothioconazole to Mycosphaerella graminicola cyp51 differs from that of other azole antifungals
    Applied and Environmental Microbiology, 2011
    Co-Authors: Josie E Parker, H J Cools, J A Lucas, B A Fraaije, Diane E Kelly, Andrew G S Warrilow, Claire M Martel, Steven L. Kelly
    Abstract:

    Prothioconazole is one of the most important commercially available demethylase inhibitors (DMIs) used to treat Mycosphaerella graminicola infection of wheat, but specific information regarding its mode of action is not available in the scientific literature. Treatment of wild-type M. graminicola (strain IPO323) with 5 μg of epoxiconazole, tebuconazole, triadimenol, or prothioconazole ml−1 resulted in inhibition of M. graminicola CYP51 (MgCYP51), as evidenced by the accumulation of 14α-methylated sterol substrates (lanosterol and eburicol) and the depletion of ergosterol in azole-treated cells. Successful expression of MgCYP51 in Escherichia coli enabled us to conduct spectrophotometric assays using purified 62-kDa MgCYP51 protein. Antifungal-binding studies revealed that epoxiconazole, tebuconazole, and triadimenol all bound tightly to MgCYP51, producing strong type II difference spectra (peak at 423 to 429 nm and trough at 406 to 409 nm) indicative of the formation of classical low-spin sixth-ligand complexes. Interaction of prothioconazole with MgCYP51 exhibited a novel spectrum with a peak and trough observed at 410 nm and 428 nm, respectively, indicating a different mechanism of inhibition. Prothioconazole bound to MgCYP51 with 840-fold less affinity than epoxiconazole and, unlike epoxiconazole, tebuconazole, and triadimenol, which are noncompetitive inhibitors, prothioconazole was found to be a competitive inhibitor of substrate binding. This represents the first study to validate the effect of prothioconazole on the sterol composition of M. graminicola and the first on the successful heterologous expression of active MgCYP51 protein. The binding affinity studies documented here provide novel insights into the interaction of MgCYP51 with DMIs, especially for the new triazolinethione derivative prothioconazole.

  • impact of recently emerged sterol 14α demethylase cyp51 variants of Mycosphaerella graminicola on azole fungicide sensitivity
    Applied and Environmental Microbiology, 2011
    Co-Authors: H J Cools, J A Lucas, B A Fraaije, Jonathan G L Mullins, Josie E Parker, Diane E Kelly, Steven L. Kelly
    Abstract:

    The progressive decline in the effectiveness of some azole fungicides in controlling Mycosphaerella graminicola, causal agent of the damaging Septoria leaf blotch disease of wheat, has been correlated with the selection and spread in the pathogen population of specific mutations in the M. graminicola CYP51 (MgCYP51) gene encoding the azole target sterol 14α-demethylase. Recent studies have suggested that the emergence of novel MgCYP51 variants, often harboring substitution S524T, has contributed to a decrease in the efficacy of prothioconazole and epoxiconazole, the two currently most effective azole fungicides against M. graminicola. In this study, we establish which amino acid alterations in novel MgCYP51 variants have the greatest impact on azole sensitivity and protein function. We introduced individual and combinations of identified alterations by site-directed mutagenesis and functionally determined their impact on azole sensitivity by expression in a Saccharomyces cerevisiae mutant YUG37::erg11 carrying a regulatable promoter controlling native CYP51 expression. We demonstrate that substitution S524T confers decreased sensitivity to all azoles when introduced alone or in combination with Y461S. In addition, S524T restores the function in S. cerevisiae of MgCYP51 variants carrying the otherwise lethal alterations Y137F and V136A. Sensitivity tests of S. cerevisiae transformants expressing recently emerged MgCYP51 variants carrying combinations of alterations D134G, V136A, Y461S, and S524T reveal a substantial impact on sensitivity to the currently most widely used azoles, including epoxiconazole and prothioconazole. Finally, we exploit a recently developed model of the MgCYP51 protein to predict that the substantial structural changes caused by these novel combinations reduce azole interactions with critical residues in the binding cavity, thereby causing resistance.

  • molecular modelling of the emergence of azole resistance in Mycosphaerella graminicola
    PLOS ONE, 2011
    Co-Authors: Jonathan G L Mullins, H J Cools, J A Lucas, B A Fraaije, Josie E Parker, Diane E Kelly, Roberto C Togawa, Steven L. Kelly
    Abstract:

    A structural rationale for recent emergence of azole (imidazole and triazole) resistance associated with CYP51 mutations in the wheat pathogen Mycosphaerella graminicola is presented, attained by homology modelling of the wild type protein and 13 variant proteins. The novel molecular models of M. graminicola CYP51 are based on multiple homologues, individually identified for each variant, rather than using a single structural scaffold, providing a robust structure-function rationale for the binding of azoles, including important fungal specific regions for which no structural information is available. The wild type binding pocket reveals specific residues in close proximity to the bound azole molecules that are subject to alteration in the variants. This implicates azole ligands as important agents exerting selection on specific regions bordering the pocket, that become the focus of genetic mutation events, leading to reduced sensitivity to that group of related compounds. Collectively, the models account for several observed functional effects of specific alterations, including loss of triadimenol sensitivity in the Y137F variant, lower sensitivity to tebuconazole of I381V variants and increased resistance to prochloraz of V136A variants. Deletion of Y459 and G460, which brings about removal of that entire section of beta turn from the vicinity of the binding pocket, confers resistance to tebuconazole and epoxiconazole, but sensitivity to prochloraz in variants carrying a combination of A379G I381V ΔY459/G460. Measurements of binding pocket volume proved useful in assessment of scope for general resistance to azoles by virtue of their accommodation without bonding interaction, particularly when combined with analysis of change in positions of key amino acids. It is possible to predict the likely binding orientation of an azole molecule in any of the variant CYPs, providing potential for an in silico screening system and reliable predictive approach to assess the probability of particular variants exhibiting resistance to particular azole fungicides.

H J Cools - One of the best experts on this subject based on the ideXlab platform.

  • update on mechanisms of azole resistance in Mycosphaerella graminicola and implications for future control
    Pest Management Science, 2013
    Co-Authors: H J Cools, B A Fraaije
    Abstract:

    This review summarises recent investigations into the molecular mechanisms responsible for the decline in sensitivity to azole (imidazole and triazole) fungicides in European populations of the Septoria leaf blotch pathogen, Mycosphaerella graminicola. The complex recent evolution of the azole target sterol 14a-demethylase (MgCYP51) enzyme in response to selection by the sequential introduction of progressively more effective azoles is described, and the contribution of individual MgCYP51 amino acid alterations and their combinations to azole resistance phenotypes and intrinsic enzyme activity is discussed. In addition, the recent identification of mechanisms independent of changes in MgCYP51 structure correlated with novel azole cross-resistant phenotypes suggests that the further evolution of M. graminicola under continued selection by azole fungicides could involve multiple mechanisms. The prospects for azole fungicides in controlling European M. graminicola populations in the future are discussed in the context of these new findings. Copyright (C) 2012 Society of Chemical Industry

  • update on mechanisms of azole resistance in Mycosphaerella graminicola and implications for future control
    Pest Management Science, 2013
    Co-Authors: H J Cools, B A Fraaije
    Abstract:

    This review summarises recent investigations into the molecular mechanisms responsible for the decline in sensitivity to azole (imidazole and triazole) fungicides in European populations of the Septoria leaf blotch pathogen, Mycosphaerella graminicola. The complex recent evolution of the azole target sterol 14α-demethylase (MgCYP51) enzyme in response to selection by the sequential introduction of progressively more effective azoles is described, and the contribution of individual MgCYP51 amino acid alterations and their combinations to azole resistance phenotypes and intrinsic enzyme activity is discussed. In addition, the recent identification of mechanisms independent of changes in MgCYP51 structure correlated with novel azole cross-resistant phenotypes suggests that the further evolution of M. graminicola under continued selection by azole fungicides could involve multiple mechanisms. The prospects for azole fungicides in controlling European M. graminicola populations in the future are discussed in the context of these new findings.

  • mechanism of binding of prothioconazole to Mycosphaerella graminicola cyp51 differs from that of other azole antifungals
    Applied and Environmental Microbiology, 2011
    Co-Authors: Josie E Parker, H J Cools, J A Lucas, B A Fraaije, Diane E Kelly, Andrew G S Warrilow, Claire M Martel, Steven L. Kelly
    Abstract:

    Prothioconazole is one of the most important commercially available demethylase inhibitors (DMIs) used to treat Mycosphaerella graminicola infection of wheat, but specific information regarding its mode of action is not available in the scientific literature. Treatment of wild-type M. graminicola (strain IPO323) with 5 μg of epoxiconazole, tebuconazole, triadimenol, or prothioconazole ml−1 resulted in inhibition of M. graminicola CYP51 (MgCYP51), as evidenced by the accumulation of 14α-methylated sterol substrates (lanosterol and eburicol) and the depletion of ergosterol in azole-treated cells. Successful expression of MgCYP51 in Escherichia coli enabled us to conduct spectrophotometric assays using purified 62-kDa MgCYP51 protein. Antifungal-binding studies revealed that epoxiconazole, tebuconazole, and triadimenol all bound tightly to MgCYP51, producing strong type II difference spectra (peak at 423 to 429 nm and trough at 406 to 409 nm) indicative of the formation of classical low-spin sixth-ligand complexes. Interaction of prothioconazole with MgCYP51 exhibited a novel spectrum with a peak and trough observed at 410 nm and 428 nm, respectively, indicating a different mechanism of inhibition. Prothioconazole bound to MgCYP51 with 840-fold less affinity than epoxiconazole and, unlike epoxiconazole, tebuconazole, and triadimenol, which are noncompetitive inhibitors, prothioconazole was found to be a competitive inhibitor of substrate binding. This represents the first study to validate the effect of prothioconazole on the sterol composition of M. graminicola and the first on the successful heterologous expression of active MgCYP51 protein. The binding affinity studies documented here provide novel insights into the interaction of MgCYP51 with DMIs, especially for the new triazolinethione derivative prothioconazole.

  • impact of recently emerged sterol 14α demethylase cyp51 variants of Mycosphaerella graminicola on azole fungicide sensitivity
    Applied and Environmental Microbiology, 2011
    Co-Authors: H J Cools, J A Lucas, B A Fraaije, Jonathan G L Mullins, Josie E Parker, Diane E Kelly, Steven L. Kelly
    Abstract:

    The progressive decline in the effectiveness of some azole fungicides in controlling Mycosphaerella graminicola, causal agent of the damaging Septoria leaf blotch disease of wheat, has been correlated with the selection and spread in the pathogen population of specific mutations in the M. graminicola CYP51 (MgCYP51) gene encoding the azole target sterol 14α-demethylase. Recent studies have suggested that the emergence of novel MgCYP51 variants, often harboring substitution S524T, has contributed to a decrease in the efficacy of prothioconazole and epoxiconazole, the two currently most effective azole fungicides against M. graminicola. In this study, we establish which amino acid alterations in novel MgCYP51 variants have the greatest impact on azole sensitivity and protein function. We introduced individual and combinations of identified alterations by site-directed mutagenesis and functionally determined their impact on azole sensitivity by expression in a Saccharomyces cerevisiae mutant YUG37::erg11 carrying a regulatable promoter controlling native CYP51 expression. We demonstrate that substitution S524T confers decreased sensitivity to all azoles when introduced alone or in combination with Y461S. In addition, S524T restores the function in S. cerevisiae of MgCYP51 variants carrying the otherwise lethal alterations Y137F and V136A. Sensitivity tests of S. cerevisiae transformants expressing recently emerged MgCYP51 variants carrying combinations of alterations D134G, V136A, Y461S, and S524T reveal a substantial impact on sensitivity to the currently most widely used azoles, including epoxiconazole and prothioconazole. Finally, we exploit a recently developed model of the MgCYP51 protein to predict that the substantial structural changes caused by these novel combinations reduce azole interactions with critical residues in the binding cavity, thereby causing resistance.

  • molecular modelling of the emergence of azole resistance in Mycosphaerella graminicola
    PLOS ONE, 2011
    Co-Authors: Jonathan G L Mullins, H J Cools, J A Lucas, B A Fraaije, Josie E Parker, Diane E Kelly, Roberto C Togawa, Steven L. Kelly
    Abstract:

    A structural rationale for recent emergence of azole (imidazole and triazole) resistance associated with CYP51 mutations in the wheat pathogen Mycosphaerella graminicola is presented, attained by homology modelling of the wild type protein and 13 variant proteins. The novel molecular models of M. graminicola CYP51 are based on multiple homologues, individually identified for each variant, rather than using a single structural scaffold, providing a robust structure-function rationale for the binding of azoles, including important fungal specific regions for which no structural information is available. The wild type binding pocket reveals specific residues in close proximity to the bound azole molecules that are subject to alteration in the variants. This implicates azole ligands as important agents exerting selection on specific regions bordering the pocket, that become the focus of genetic mutation events, leading to reduced sensitivity to that group of related compounds. Collectively, the models account for several observed functional effects of specific alterations, including loss of triadimenol sensitivity in the Y137F variant, lower sensitivity to tebuconazole of I381V variants and increased resistance to prochloraz of V136A variants. Deletion of Y459 and G460, which brings about removal of that entire section of beta turn from the vicinity of the binding pocket, confers resistance to tebuconazole and epoxiconazole, but sensitivity to prochloraz in variants carrying a combination of A379G I381V ΔY459/G460. Measurements of binding pocket volume proved useful in assessment of scope for general resistance to azoles by virtue of their accommodation without bonding interaction, particularly when combined with analysis of change in positions of key amino acids. It is possible to predict the likely binding orientation of an azole molecule in any of the variant CYPs, providing potential for an in silico screening system and reliable predictive approach to assess the probability of particular variants exhibiting resistance to particular azole fungicides.

K E Hammondkosack - One of the best experts on this subject based on the ideXlab platform.

  • Mycosphaerella graminicola lysm effector mediated stealth pathogenesis subverts recognition through both cerk1 and cebip homologues in wheat
    Molecular Plant-microbe Interactions, 2014
    Co-Authors: Wingsham Lee, K E Hammondkosack, J J Rudd, K Kanyuka
    Abstract:

    Fungal cell-wall chitin is a well-recognized pathogen-associated molecular pattern. Recognition of chitin in plants by pattern recognition receptors activates pathogen-triggered immunity (PTI). In Arabidopsis, this process is mediated by a plasma membrane receptor kinase, CERK1, whereas in rice, a receptor-like protein, CEBiP, in addition to CERK1 is required. Secreted chitin-binding lysin motif (LysM) containing fungal effector proteins, such as Ecp6 from the biotrophic fungus Cladosporium fulvum, have been reported to interfere with PTI. Here, we identified wheat homologues of CERK1 and CEBiP and investigated their role in the interaction with the nonbiotrophic pathogen of wheat Mycosphaerella graminicola (synonym Zymoseptoria tritici). We show that silencing of either CERK1 or CEBiP in wheat, using Barley stripe mosaic virus-mediated virus-induced gene silencing, is sufficient in allowing leaf colonization by the normally nonpathogenic M. graminicola Mg3LysM (homologue of Ecp6) deletion mutant, while the Mg1LysM deletion mutant was fully pathogenic toward both silenced and wild-type wheat leaves. These data indicate that Mg3LysM is important for fungal evasion of PTI in wheat leaf tissue and that both CERK1 and CEBiP are required for activation of chitin-induced defenses, a feature conserved between rice and wheat, and perhaps, also in other cereal species.

  • defining the predicted protein secretome of the fungal wheat leaf pathogen Mycosphaerella graminicola
    PLOS ONE, 2012
    Co-Authors: Alexandre Morais Do Amaral, J J Rudd, J F Antoniw, K E Hammondkosack
    Abstract:

    The Dothideomycete fungus Mycosphaerella graminicola is the causal agent of Septoria tritici blotch, a devastating disease of wheat leaves that causes dramatic decreases in yield. Infection involves an initial extended period of symptomless intercellular colonisation prior to the development of visible necrotic disease lesions. Previous functional genomics and gene expression profiling studies have implicated the production of secreted virulence effector proteins as key facilitators of the initial symptomless growth phase. In order to identify additional candidate virulence effectors, we re-analysed and catalogued the predicted protein secretome of M. graminicola isolate IPO323, which is currently regarded as the reference strain for this species. We combined several bioinformatic approaches in order to increase the probability of identifying truly secreted proteins with either a predicted enzymatic function or an as yet unknown function. An initial secretome of 970 proteins was predicted, whilst further stringent selection criteria predicted 492 proteins. Of these, 321 possess some functional annotation, the composition of which may reflect the strictly intercellular growth habit of this pathogen, leaving 171 with no functional annotation. This analysis identified a protein family encoding secreted peroxidases/chloroperoxidases (PF01328) which is expanded within all members of the family Mycosphaerellaceae. Further analyses were done on the non-annotated proteins for size and cysteine content (effector protein hallmarks), and then by studying the distribution of homologues in 17 other sequenced Dothideomycete fungi within an overall total of 91 predicted proteomes from fungal, oomycete and nematode species. This detailed M. graminicola secretome analysis provides the basis for further functional and comparative genomics studies.

  • aberrant protein n glycosylation impacts upon infection related growth transitions of the haploid plant pathogenic fungus Mycosphaerella graminicola
    Molecular Microbiology, 2011
    Co-Authors: J Motteram, K E Hammondkosack, Alison Lovegrove, Elizabeth Pirie, Justin T Marsh, Jean Devonshire, Allison M L Van De Meene, J J Rudd
    Abstract:

    The ascomycete fungus Mycosphaerella graminicola is the causal agent of Septoria Tritici Blotch disease of wheat and can grow as yeast-like cells or as hyphae depending on environmental conditions. Hyphal growth is however essential for successful leaf infection. A T-DNA mutagenesis screen performed on haploid spores identified a mutant, which can undergo yeast-like growth but cannot switch to hyphal growth. For this reason the mutant was non-pathogenic towards wheat leaves. The gene affected, MgAlg2, encoded a homologue of Saccharomyces cerevisiae ScAlg2, an alpha-1,2-mannosyltransferase, which functions in the early stages of asparagine-linked protein (N-) glycosylation. Targeted gene deletion and complementation experiments confirmed that loss of MgAlg2 function prevented the developmental growth switch. MgAlg2 was able to functionally complement the S. cerevisiae ScAlg2-1 temperature sensitive growth phenotype. Spores of ΔMgAlg2 mutants were hypersensitive to the cell wall disrupting agent Calcofluor white and produced abnormally hypo-N-glycosylated proteins. Gene expression, proteome and glycoproteome analysis revealed that ΔMgAlg2 mutant spores show responses typically associated with the accumulation of mis-folded proteins. The data presented highlight key roles for protein N-glycosylation in regulating the switch to hyphal growth, possibly as a consequence of maintaining correct folding and localization of key proteins involved in this process.

  • identification and characterisation of Mycosphaerella graminicola secreted or surface associated proteins with variable intragenic coding repeats
    Fungal Genetics and Biology, 2010
    Co-Authors: J J Rudd, B A Fraaije, J F Antoniw, J Motteram, Rosalind Marshall, K E Hammondkosack
    Abstract:

    Abstract Pathogenic micro-organisms have been suggested to vary the number of intragenic repeats present within secreted or cell membrane/cell wall-associated proteins in order to manipulate host immune responses. We have identified a number of genes predicted to encode secreted proteins possessing internal tandem repeats in the genome sequence of Mycosphaerella graminicola (isolate IPO323), a wheat leaf-specific fungal pathogen and causal agent of Septoria tritici blotch disease. Twenty-three M. graminicola Tandem Repeat Proteins (MgTRPs) were subject to further analysis. Many MgTRPs varied in the number of intragenic repeats between isolates and almost all were expressed. Peak gene expression was frequently observed towards the end of the symptomless phase of wheat leaf colonisation which typically lasts for 8–10 days after inoculation. In contrast, with one exception, increased expression of the majority of MgTRPs was not detected during interactions with resistant host genotypes. Repeat number differences detected in genomic DNA were retained in different transcript sizes produced during plant infection by different isolates. One in planta expressed MgTRP was found to reside within a ∼6 kb region that appears to be absent from a number of tested isolates and also from individual members of a modern field population. Sequence analysis of another in planta expressed MgTRP from six isolates highlighted the potential for structural changes which may occur as a consequence of varying internal repeat numbers and provided support for repeat variation occurring as a consequence of intragenic recombination. These data provide new insights into the genetic variation which exists within M. graminicola populations at the level of in planta expressed secreted/surface-associated proteins which are candidate effectors in the host–pathogen interaction.

  • phenotypic and genetic analysis of the triticum monococcum Mycosphaerella graminicola interaction
    New Phytologist, 2008
    Co-Authors: Hai-chun Jing, Gert H. J. Kema, D. J. Lovell, R. J. Gutteridge, Daniel Jenk, D. Kornyukhin, O. P. Mitrofanova, K E Hammondkosack
    Abstract:

    Here, the aim was to understand the cellular and genetic basis of the Triticum monococcum-Mycosphaerella graminicola interaction. Testing for 5 yr under UK field conditions revealed that all 24 T. monococcum accessions exposed to a high level of natural inocula were fully resistant to M. graminicola. When the accessions were individually inoculated in the glasshouse using an attached leaf seeding assay and nine previously characterized M. graminicola isolates, fungal sporulation was observed in only three of the 216 interactions examined. Microscopic analyses revealed that M. graminicola infection was arrested at four different stages post-stomatal entry. When the inoculated leaves were detached 30 d post inoculation and incubated at 100% humidity, abundant asexual sporulation occurred within 5 d in a further 61 interactions. An F2 mapping population generated from a cross between T. monococcum accession MDR002 (susceptible) and MDR043 (resistant) was inoculated with the M. graminicola isolate IPO323. Both resistance and in planta fungal growth were found to be controlled by a single genetic locus designated as TmStb1 which was linked to the microsatellite locus Xbarc174 on chromosome 7Am. Exploitation of T. monococcum may provide new sources of resistance to septoria tritici blotch disease.

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