H. B. Deising scite author profile

Infection structures of phytopathogenic fungi are modified hyphae specialized for the invasion of plant tissues. Initial events are adhesion to the cuticle and directed growth of the germ tube on the plant surface. At the site of penetration, appressoria are often formed that may have melanized walls and develop high turgor pressure to support the penetration process. The penetration hypha accumulates components of the cytoskeleton in the tip and secretes a variety of cell wall-degrading enzymes in a highly regulated fashion in order to penetrate the cuticle and the plant cell wall. This article reviews recent papers on the cytology, physiology, and molecular biology of the penetration process.

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When and how to kill a plant cell: Infection strategies of plant pathogenic fungi

Horbach

Navarro-Quesada

Knogge

et al. 2011

Journal of Plant Physiology

340

217

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Developmentally regulated conversion of surface‐exposed chitin to chitosan in cell walls of plant pathogenic fungi

et al. 2002

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Summary• Conversion of surface-exposed chitin to chitosan in cell walls of in vitro -and in vivo -differentiated infection structures of two rust fungi, the wheat stem rust fungus Puccinia graminis f. sp. tritici and the broad bean rust fungus Uromyces fabae , and of the causal agent of maize anthracnose, Colletotrichum graminicola , were studied.• Epi-fluorescence microscopy with the fluorescence-labeled lectin wheat germ agglutinin (WGA) revealed that surfaces of infection structures formed on the plant cuticle expose chitin, whereas surfaces of structures formed after invading the host do not.• To identify chitin modification by de-N -acetylation, we raised polyclonal antibodies specifically recognizing de-N -acetylated chitosan. These antibodies labeled only those infection structures that differentiate inside the plant, indicating that chitosan is exposed on cell wall surfaces post penetration.• Surface modification of the fungal cell walls by chitin de-N -acetylation is discussed as a fungal strategy to protect cell walls of pathogenic hyphae from enzymatic hydrolysis by host chitinases, and to avoid generation of an auto-catalytic defense response system in the invaded host tissue.

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Optical Measurements of Invasive Forces Exerted by Appressoria of a Plant Pathogenic Fungus

Bechinger¹,

Giebel²,

Schnell³

et al. 1999

Science

250

142

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Many plant pathogenic fungi, such as the cereal pathogen Colletotrichum graminicola , differentiate highly specialized infection structures called appressoria, which send a penetration peg into the underlying plant cell. Appressoria have been shown to generate enormous turgor pressure, but direct evidence for mechanical infection of plants by fungi is lacking. A microscopic method was developed that uses elastic optical waveguides to visualize and measure forces locally exerted by single appressoria. By this method, the force exerted by appressoria of C. graminicola was found to be about 17 micronewtons.

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Development of a novel multiplex DNA microarray for Fusarium graminearum and analysis of azole fungicide responses

et al. 2011

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BackgroundThe toxigenic fungal plant pathogen Fusarium graminearum compromises wheat production worldwide. Azole fungicides play a prominent role in controlling this pathogen. Sequencing of its genome stimulated the development of high-throughput technologies to study mechanisms of coping with fungicide stress and adaptation to fungicides at a previously unprecedented precision. DNA-microarrays have been used to analyze genome-wide gene expression patterns and uncovered complex transcriptional responses. A recently developed one-color multiplex array format allowed flexible, effective, and parallel examinations of eight RNA samples.ResultsWe took advantage of the 8 × 15 k Agilent format to design, evaluate, and apply a novel microarray covering the whole F. graminearum genome to analyze transcriptional responses to azole fungicide treatment. Comparative statistical analysis of expression profiles uncovered 1058 genes that were significantly differentially expressed after azole-treatment. Quantitative RT-PCR analysis for 31 selected genes indicated high conformity to results from the microarray hybridization. Among the 596 genes with significantly increased transcript levels, analyses using GeneOntology and FunCat annotations detected the ergosterol-biosynthesis pathway genes as the category most significantly responding, confirming the mode-of-action of azole fungicides. Cyp51A, which is one of the three F. graminearum paralogs of Cyp51 encoding the target of azoles, was the most consistently differentially expressed gene of the entire study. A molecular phylogeny analyzing the relationships of the three CYP51 proteins in the context of 38 fungal genomes belonging to the Pezizomycotina indicated that CYP51C (FGSG_11024) groups with a new clade of CYP51 proteins. The transcriptional profiles for genes encoding ABC transporters and transcription factors suggested several involved in mechanisms alleviating the impact of the fungicide. Comparative analyses with published microarray experiments obtained from two different nutritional stress conditions identified subsets of genes responding to different types of stress. Some of the genes that responded only to tebuconazole treatment appeared to be unique to the F. graminearum genome.ConclusionsThe novel F. graminearum 8 × 15 k microarray is a reliable and efficient high-throughput tool for genome-wide expression profiling experiments in fungicide research, and beyond, as shown by our data obtained for azole responses. The array data contribute to understanding mechanisms of fungicide resistance and allow identifying fungicide targets.

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H. B. Deising

Morphogenesis and Mechanisms of Penetration by Plant Pathogenic Fungi

When and how to kill a plant cell: Infection strategies of plant pathogenic fungi

Developmentally regulated conversion of surface‐exposed chitin to chitosan in cell walls of plant pathogenic fungi

Optical Measurements of Invasive Forces Exerted by Appressoria of a Plant Pathogenic Fungus

Development of a novel multiplex DNA microarray for Fusarium graminearum and analysis of azole fungicide responses

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