Transcriptome of an <scp>A</scp>rmillaria root disease pathogen reveals candidate genes involved in host substrate utilization at the host–pathogen interface

Ross‐Davis, Amy L.; Stewart, Jane E.; Hanna, John W.; Kim, M.-S.; Knaus, Brian J.; Cronn, Richard; Rai, Hardeep; Richardson, Bryce A.; McDonald, Geral I.; Klopfenstein, Ned B.

doi:10.1111/efp.12056

Cited by 38 publications

(50 citation statements)

References 89 publications

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“…Despite their huge impact on forestry, horticulture and agriculture, the genetics of the pathogenicity of Armillaria species is poorly understood. The only -omics data published so far have highlighted a substantial repertoire of plant cell wall degrading enzymes (PCWDE) and secreted proteins, among others, in A. mellea and A. solidipes 11,12 , while analyses of the genomes of other pathogenic basidiomycetes (such as Moniliophthora 13,14 , Heterobasidion 15 and Rhizoctonia 16 ) identified genes coding for PCWDEs, secreted and effector proteins or secondary metabolism (SM) as putative pathogenicity factors. However, the lifecycle and unique dispersal strategy of Armillaria prefigure other evolutionary routes to pathogenicity, which, along with other potential genomic factors (such as transposable elements 17 ) are not yet known.…”

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confidence: 99%

Genome expansion and lineage-specific genetic innovations in the forest pathogenic fungi Armillaria

et al. 2017

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T he genus Armillaria causes root rot disease in both gymnoand angiosperms, in forests, parks, and even vineyards in more than 500 host plant species 1 across the world. Most Armillaria species are facultative necrotrophs, which, after colonizing and killing the root cambium, transition to a saprobic phase, decomposing dead woody tissues of the host. As saprotrophs, Armillaria spp. are white rot (WR) fungi, which can efficiently decompose all components of plant cell walls, including lignin, (hemi-)cellulose and pectin 2 . They produce fleshy fruiting bodies (honey mushrooms) that appear in large clumps around infected plants and produce sexual spores. The vegetative phase of Armillaria is predominantly diploid rather than dikaryotic like most basidiomycetes.Individuals of Armillaria can reach immense sizes and include the 'humongous fungus' , one of the largest terrestrial organisms on Earth 3 , measuring up to 965 hectares and 600 tons 4 , and can display a mutation rate ≅ 3 orders of magnitude lower than most filamentous fungi 5 . Individuals reach this immense size via growing rhizomorphs, dark mycelial strings 1-4 mm wide that allow the fungus to bridge gaps between food sources or host plants 1,6 (hence the name shoestring root rot). Rhizomorphs develop through the aggregation and coordinated parallel growth of hyphae, similar to some fruiting body tissues 7,8 . As migratory and exploratory organs, rhizomorphs can grow approximately 1 m yr −1 and cross several metres underground in search for new hosts, although roles in uptake and longrange translocation of nutrients have also been proposed 1,9,10 . Root contact by rhizomorphs is the main mode of infection by the fungus, which makes the prevention of recurrent infection in Armillariacontaminated areas particularly difficult 1 . Despite their huge impact on forestry, horticulture and agriculture, the genetics of the pathogenicity of Armillaria species is poorly understood. The only -omics data published so far have highlighted a substantial repertoire of plant cell wall degrading enzymes (PCWDE) and secreted proteins, among others, in A. mellea and A. solidipes 11,12 , while analyses of the genomes of other pathogenic basidiomycetes (such as Moniliophthora 13,14 , Heterobasidion 15 and Rhizoctonia 16 ) identified genes coding for PCWDEs, secreted and effector proteins or secondary metabolism (SM) as putative pathogenicity factors. However, the lifecycle and unique dispersal strategy of Armillaria prefigure other evolutionary routes to pathogenicity, which, along with other potential genomic factors (such as transposable elements 17 ) are not yet known.Here, we investigate genome evolution and the origin of pathogenicity in Armillaria using comparative genomics, transcriptomics

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Genome expansion and lineage-specific genetic innovations in the forest pathogenic fungi Armillaria

et al. 2017

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“…Basidiospores are unimportant in infection and no asexual reproductive stage is known (Mwenje et al., 1998, Rizzo et al., 1998, Hood et al., 2008). To penetrate plant roots, rhizomorphs grow appressed to the root surface and produce lateral branches that secrete an assortment of cell wall degrading enzymes such as laccases, pectin lyases, peroxidases, polygalacturonases and suberinases (Mwenje and Ride, 1999, Baumgartner et al., 2011, Ross-Davis et al., 2013). After penetrating the root, hyphae subsequently spread through the phloem and secondary xylem in parallel to the cambium and colonise the surrounding tissues, growing as a mycelial fan through the roots and causing necrotic lesions (Fig.…”

Section: Pathogenic Basidiomycetesmentioning

confidence: 99%

“…2013) which has revealed a 58.35 Mb genome, proteomic and transcriptomic data (Collins et al., 2013, Ross-Davis et al., 2013), an Agrobacterium tumefaciens -based method for transformation of basidiospores (Baumgartner et al. 2010) together with a system of producing basidiospores in vitro (Ford et al.…”

Section: Pathogenic Basidiomycetesmentioning

confidence: 99%

The good, the bad and the tasty: The many roles of mushrooms

Mattos-Shipley¹,

Ford²,

Alberti³

et al. 2016

Studies in Mycology

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Fungi are often inconspicuous in nature and this means it is all too easy to overlook their importance. Often referred to as the “Forgotten Kingdom”, fungi are key components of life on this planet. The phylum Basidiomycota, considered to contain the most complex and evolutionarily advanced members of this Kingdom, includes some of the most iconic fungal species such as the gilled mushrooms, puffballs and bracket fungi. Basidiomycetes inhabit a wide range of ecological niches, carrying out vital ecosystem roles, particularly in carbon cycling and as symbiotic partners with a range of other organisms. Specifically in the context of human use, the basidiomycetes are a highly valuable food source and are increasingly medicinally important. In this review, seven main categories, or ‘roles’, for basidiomycetes have been suggested by the authors: as model species, edible species, toxic species, medicinal basidiomycetes, symbionts, decomposers and pathogens, and two species have been chosen as representatives of each category. Although this is in no way an exhaustive discussion of the importance of basidiomycetes, this review aims to give a broad overview of the importance of these organisms, exploring the various ways they can be exploited to the benefit of human society.

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“…[7, 8, 19]. Less is known about the fungal component of these pathosystems, although recent studies have begun to shed light on molecular strategies utilized by the pathogens [12–19]. The current study represents the first analysis of genes expressed by the causal agent of laminated root rot, Phellinus sulphurascens .…”

Section: Discussionmentioning

confidence: 99%

“…A small but growing number of studies have examined genes expressed in conifer pathogens, including Armillaria solidipes , a white-rot root disease pathogen [12], Grosmannia clavigera , a mountain pine beetle-associated pathogen of lodgepole pine [13, 14], and Heterobasidion annosum sensu lato , a complex of closely related white-rot basidiomycetes that causes wood-decay in pine, spruce and fir trees [15–17], reviewed in [18]. In this study, we utilized expressed sequence tag (EST) sequencing to discover some of the fungal genes expressed during the Ps -DF interaction.…”

Section: Introductionmentioning

confidence: 99%

Gene expression profiling of candidate virulence factors in the laminated root rot pathogen Phellinus sulphurascens

et al. 2014

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BackgroundPhellinus sulphurascens is a fungal pathogen that causes laminar root rot in conifers, one of the most damaging root diseases in western North America. Despite its importance as a forest pathogen, this fungus is still poorly studied at the genomic level. An understanding of the molecular events involved in establishment of the disease should help to develop new methods for control of this disease.ResultsWe generated over 4600 expressed sequence tags from two cDNA libraries constructed using either mycelia grown on cellophane sheets and exposed to Douglas-fir roots or tissues from P. sulphurascens-infected Douglas-fir roots. A total of 890 unique genes were identified from the two libraries, and functional classification of 636 of these genes was possible using the Functional Catalogue (FunCat) annotation scheme. cDNAs were identified that encoded 79 potential virulence factors, including numerous genes implicated in virulence in a variety of phytopathogenic fungi. Many of these putative virulence factors were also among 82 genes identified as encoding putatively secreted proteins. The expression patterns of 86 selected fungal genes over 7 days of infection of Douglas-fir were examined using real-time PCR, and those significantly up-regulated included rhamnogalacturonan acetylesterase, 1,4-benzoquinone reductase, a cyclophilin, a glucoamylase, 3 hydrophobins, a lipase, a serine carboxypeptidase, a putative Ran-binding protein, and two unknown putatively secreted proteins called 1 J04 and 2 J12. Significantly down-regulated genes included a manganese-superoxide dismutase, two metalloproteases, and an unknown putatively secreted protein called Ps0058.ConclusionsThis first collection of Phellinus sulphurascens EST sequences and its annotation provide an important resource for future research aimed at understanding key virulence factors of this forest pathogen. We examined the expression patterns of numerous fungal genes with potential roles in virulence, and found a collection of functionally diverse genes that are significantly up- or down-regulated during infection of Douglas-fir seedling roots by P. sulphurascens.Electronic supplementary materialThe online version of this article (doi:10.1186/1471-2164-15-603) contains supplementary material, which is available to authorized users.

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Transcriptome of an Armillaria root disease pathogen reveals candidate genes involved in host substrate utilization at the host–pathogen interface

Cited by 38 publications

References 89 publications

Genome expansion and lineage-specific genetic innovations in the forest pathogenic fungi Armillaria

Genome expansion and lineage-specific genetic innovations in the forest pathogenic fungi Armillaria

The good, the bad and the tasty: The many roles of mushrooms

Gene expression profiling of candidate virulence factors in the laminated root rot pathogen Phellinus sulphurascens

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