Convergent losses of decay mechanisms and rapid turnover of symbiosis genes in mycorrhizal mutualists

Kohler, Annegret; Kuo, Alan; Nagy, László G.; Morin, Emmanuelle; Barry, Kerrie; Buscot, François; Canbäck, Björn; Choi, Cindy; Cichocki, Nicolas; Clum, Alicia; Colpaert, Jan; Copeland, Alex; Costa, Maurício Dutra; Doré, Jeanne; Floudas, Dimitrios; Girlanda, Mariangela; Henrissat, Bernard; Herrmann, Sylvie; Hess, Jaqueline; Högberg, Nils; Johansson, Tomas; Khouja, Hassine‐Radhouane; LaButti, Kurt; Lahrmann, Urs; Levasseur, Anthony; Lindquist, Erika; Lipzen, Anna; Marmeisse, Roland; Martino, Elena; Murat, Claude; Ngan, Chew Yee; Nehls, Uwe; Plett, Jonathan M.; Pringle, Anne; Ohm, Robin A.; Perotto, Silvia; Peter, Martina; Riley, Robert; Rineau, François; Ruytinx, Joske; Salamov, Asaf; Shah, Firoz; Sun, Hui; Tarkka, Mika; Tritt, Andrew; Veneault‐Fourrey, Claire; Zuccaro, Alga; Tunlid, Anders; Grigoriev, Igor V.; Hibbett, David S.; Martin, Francis

doi:10.1038/ng.3223

Cited by 844 publications

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“…These include terpene cyclases, non-ribosomal peptide synthase-like prenyl transferases, and halogenases, as well as trichodiene and polyprenyl synthases, which have been linked to fungal pathogenesis, virulence and competition with other microbes 26 . Small secreted proteins (SSPs, < 300 amino acids with a secretory signal) can act as effectors in mutualistic and pathogenic interactions in various fungal groups 19,27 . On average, we found more SSPs (n = 669) in Armillaria species (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…Palaeoagaricites antiquus (100-110 Myr) is the oldest fossil can be placed within Agaricales 75 , hence we constrained the MRCAs of this order to a minimum age of 108 Myr. To define the minimum age constraint of the origin of Boletales to 84 Myr, we referred to published analyses 27 . Maximum age constraints were defined with a wide safety window to allow for the calibrated clades to be inferred at least twice as old as their minimum ages.…”

Section: Methodsmentioning

confidence: 99%

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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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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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

et al. 2017

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“…We have selected (a) 14 popular white rot fungal strains – Ceriporiopsis subvermispora B (Fernandez-Fueyo et al 2012), Heterobasidion annosum v2.0 (Olson et al 2012), Fomitiporia mediterranea v1.0 (Floudas et al 2012), Phanerochaete carnosa HHB-10118 (Suzuki et al 2012), Pycnoporus cinnabarinus BRFM 137 (Levasseur et al 2014), Phanerochaete chrysosporium R78 v2.2 (Martinez et al 2004; Ohm et al 2014), Dichomitus squalens LYAD-421 SS1 (Floudas et al 2012), Trametes versicolor v1.0 (Floudas et al 2012), Punctularia strigosozonata v1.0 (Floudas et al 2012), Phlebia brevispora HHB-7030 SS6 (Binder et al 2013), Botrytis cinerea v1.0 (Amselem et al 2011), Pleurotus ostreatus PC15 v2.0 (Riley et al 2014; Alfaro et al 2016; Castanera et al 2016), Stereum hirsutum FP-91666 SS1 v1.0 (Floudas et al 2012), Pleurotus eryngii ATCC90797 (Guillen et al 1992; Camarero et al 1999; Ruiz‐Dueñas et al 1999; Matheny et al 2006); (b) 15 popular brown rot fungal strains – Postia placenta MAD 698-R v1.0 (Martinez et al 2009), Fibroporia radiculosa TFFH 294 (Tang et al 2012), Wolfiporia cocos MD-104 SS10 v1.0 (Floudas et al 2012), Dacryopinax primogenitus DJM 731 SSP1 v1.0 (Floudas et al 2012), Daedalea quercina v1.0 (Nagy et al 2015), Laetiporus sulphureus var v1.0 (Nagy et al 2015), Postia placenta MAD-698-R-SB12 v1.0 (Martinez et al 2009), Neolentinus lepideus v1.0 (Nagy et al 2015), Serpula lacrymans S7.9 v2.0 (Eastwood et al 2011), Calocera cornea v1.0 (Eastwood et al 2011), Gloeophyllum trabeum v1.0 (Floudas et al 2012), Fistulina hepatica v1.0 (Floudas et al 2015), Fomitopsis pinicola FP-58527 SS1 (Floudas et al 2015), Hydnomerulius pinastri v2.0 (Kohler et al 2015) and Coniophora puteana v1.0 (Kohler et al 2015); (c) 13 popular soft rot fungal strains – Trichoderma reesei v 2.0 (Martinez et al 2008), Rhizopus oryzae 99-880 from Broad (Ma et al 2009), Aspergillus wentii v1.0 (De Vries et al 2017), Penicillium chrysogenum Wisconsin 54-1255 (Van Den Berg et al 2008), Daldinia eschscholzii EC12 v1.0, Hypoxylon sp. CI-4A v1.0 (Wu et al 2017), Aspergillus niger ATCC 1015 v4.0 (Andersen et al 2011), Hypoxylon sp.…”

Section: Methodsmentioning

confidence: 99%

Comparative study of genome-wide plant biomass-degrading CAZymes in white rot, brown rot and soft rot fungi

2017

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We have conducted a genome-level comparative study of basidiomycetes wood-rotting fungi (white, brown and soft rot) to understand the total plant biomass (lignin, cellulose, hemicellulose and pectin) -degrading abilities. We have retrieved the genome-level annotations of well-known 14 white rot fungi, 15 brown rot fungi and 13 soft rot fungi. Based on the previous literature and the annotations obtained from CAZy (carbohydrate-active enzyme) database, we have separated the genome-wide CAZymes of the selected fungi into lignin-, cellulose-, hemicellulose- and pectin-degrading enzymes. Results obtained in our study reveal that white rot fungi, especially Pleurotus eryngii and Pleurotus ostreatus potentially possess high ligninolytic ability, and soft rot fungi, especially Botryosphaeria dothidea and Fusarium oxysporum sp., potentially possess high cellulolytic, hemicellulolytic and pectinolytic abilities. The total number of genes encoding for cytochrome P450 monooxygenases and metabolic processes were high in soft and white rot fungi. We have tentatively calculated the overall lignocellulolytic abilities among the selected wood-rotting fungi which suggests that white rot fungi possess higher lignin and soft rot fungi potentially possess higher cellulolytic, hemicellulolytic and pectinolytic abilities. This approach can be applied industrially to efficiently find lignocellulolytic and aromatic compound-degrading fungi based on their genomic abilities.

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“…The results have confirmed the presence of a reduced set of genes coding PCWDEs, as previously reported (Martin et al 2010). This is a common feature of all ectomycorrhizal fungi (VeneaultFourrey et al 2014;Kohler et al 2015) as well as of brown-rot fungi and the biotrophic fungus Melampsora larici-populina (Duplessis et al 2011). Enzymes targeting all of the three components of plant cell wall polysaccharides (cellulose, pectin, hemicellulose) have been identified in the T. melanosporum genome, because of their close relationship with biochemically characterized CAZymes.…”

Section: Plant Cell Wall Degrading Enzymes In T Melanosporummentioning

confidence: 99%

Understanding plant cell-wall remodelling during the symbiotic interaction between Tuber melanosporum and Corylus avellana using a carbohydrate microarray

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Fangel

Henrissat

et al. 2016

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Convergent losses of decay mechanisms and rapid turnover of symbiosis genes in mycorrhizal mutualists

Cited by 844 publications

References 23 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

Comparative study of genome-wide plant biomass-degrading CAZymes in white rot, brown rot and soft rot fungi

Understanding plant cell-wall remodelling during the symbiotic interaction between Tuber melanosporum and Corylus avellana using a carbohydrate microarray

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