Genome, transcriptome, and secretome analysis of wood decay fungus
            <i>Postia placenta</i>
            supports unique mechanisms of lignocellulose conversion

Martínez, Diego; Challacombe, Jean F.; Morgenstern, Ingo; Hibbett, David S.; Schmoll, Monika; Kubicek, Christian P.; Ferreira, Patricia; Ruíz-Dueñas, Francisco J.; Martı́nez, Ángel T.; Kersten, Philip J.; Hammel, Kenneth E.; Wymelenberg, Amber Vanden; Gaskell, Jill; Lindquist, Erika; Sabat, Grzegorz; BonDurant, Sandra Splinter; Larrondo, Luis F.; Canessa, Paulo; Vicuña, Rafael; Yadav, J. S.; Doddapaneni, Harshavardhan; Subramanian, Venkataramanan; Pisabarro, Antonio G.; Lavín, José L.; Oguiza, José A.; Master, Emma R.; Henrissat, Bernard; Coutinho, Pedro M.; Harris, Paul V.; Magnuson, Jon; Baker, Scott E.; Bruno, Kenneth S.; Kenealy, William R.; Hoegger, Patrik J.; Kües, Ursula; Ramaiya, Preethi; Lucas, Susan; Salamov, Asaf; Shapiro, Harris; Tu, Hank; Chee, Christine; Misra, Monica; Xie, Gary; Teter, Sarah; Yaver, Debbie; James, Timothy Y.; Mokrejš, Martin; Pospíšek, Martin; Grigoriev, Igor V.; Brettin, Thomas; Rokhsar, Dan; Berka, Randy M.; Cullen, Dan

doi:10.1073/pnas.0809575106

Cited by 537 publications

(528 citation statements)

References 34 publications

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“…Brown rot wood degradation has been studied mainly based on Gloeophyllum trabeum, although some mechanisms have also been confirmed in Postia placenta, Serpula lacrymans, and others (Goodell et al 1997;Shimokawa et al 2004;Martinez et al 2009). Differences between species have also been reported, which support the theory of the repeated evolution of brown rot fungi from white rot fungi (Green and Highley 1996;Hibbett and Donoghue 2001;Niemenmaa et al 2008;Kang et al 2009).…”

Section: Degradation Of Wood By Brown Rotmentioning

confidence: 57%

Mode of action of brown rot decay resistance in modified wood: a review

Ringman

Pilgård²,

Brischke

et al. 2013

Holzforschung

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Chemically or physically modified wood materials have enhanced resistance to wood decay fungi. In contrast to treatments with traditional wood preservatives, where the resistance is caused mainly by the toxicity of the chemicals added, little is known about the mode of action of nontoxic wood modification methods. This study reviews established theories related to resistance in acetylated, furfurylated, dimethylol dihydroxyethyleneurea-treated, and thermally modified wood. The main conclusion is that only one theory provides a consistent explanation for the initial inhibition of brown rot degradation in modified wood, that is, moisture exclusion via the reduction of cell wall voids. Other proposed mechanisms, such as enzyme nonrecognition, micropore blocking, and reducing the number of free hydroxyl groups, may reduce the degradation rate when cell wall water uptake is no longer impeded.

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Section: Degradation Of Wood By Brown Rotmentioning

confidence: 57%

Mode of action of brown rot decay resistance in modified wood: a review

Ringman

Pilgård²,

Brischke

et al. 2013

Holzforschung

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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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“…Phanerochaete chrysosporium) or in Fenton-type reactions (brown rot fungi, e.g. Pleurotus eryngii and Postia placenta) [65,66]. The genome of A. nidulans contains genes putatively encoding for peroxidases [42,67].…”

mentioning

confidence: 99%

Investigating Aspergillus nidulans secretome during colonisation of cork cell walls

Martins

Garcia

Varela

et al. 2014

Journal of Proteomics

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Cork, the outer bark of Quercus suber, shows a unique compositional structure, a set of remarkable properties, including high recalcitrance. Cork colonisation by Ascomycota remains largely overlooked. Herein, Aspergillus nidulans secretome on cork was analysed (2DE).Proteomic data were further complemented by microscopic (SEM) and spectroscopic (ATR-FTIR) evaluation of the colonised substrate and by targeted analysis of lignin degradation compounds (UPLC-HRMS). Data showed that the fungus formed an intricate network of hyphae around the cork cell walls, which enabled polysaccharides and lignin superficial degradation, but probably not of suberin. The degradation of polysaccharides was suggested by the identification of few polysaccharide degrading enzymes (β-glucosidases and endo-1,5--L-arabinosidase).Lignin degradation, which likely evolved throughout a Fenton-like mechanism relying on the activity of alcohol oxidases, was supported by the identification of small aromatic compounds (e.g. cinnamic acid and veratrylaldehyde) and of several putative high molecular weight lignin degradation products. In addition, cork recalcitrance was corroborated by the identification of several protein species which are associated with autolysis. Finally, stringent comparative proteomics revealed that A. nidulans colonisation of cork and wood share a common set of enzymatic mechanisms. However the higher polysaccharide accessibility in cork might explain the increase of β-glucosidase in cork secretome.

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Genome, transcriptome, and secretome analysis of wood decay fungus Postia placenta supports unique mechanisms of lignocellulose conversion

Cited by 537 publications

References 34 publications

Mode of action of brown rot decay resistance in modified wood: a review

Mode of action of brown rot decay resistance in modified wood: a review

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

Investigating Aspergillus nidulans secretome during colonisation of cork cell walls

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