Lignocellulose modifications by brown rot fungi and their effects, as pretreatments, on cellulolysis

Jonathan S. Schilling; Jun Ai; Robert A. Blanchette; Shona M. Duncan; Timothy R. Filley; Ulrike W. Tschirner

doi:10.1016/j.biortech.2012.04.018

Lignocellulose modifications by brown rot fungi and their effects, as pretreatments, on cellulolysis

Jonathan S. Schilling, Jun Ai, Robert A. Blanchette, Shona M. Duncan, Timothy R. Filley, Ulrike W. Tschirner

Research output: Contribution to journal › Article › peer-review

64 Scopus citations

Abstract

Brown rot fungi Gloeophyllum trabeum and Postia placenta were used to degrade aspen, spruce, or corn stover over 16. weeks. Decayed residues were saccharified using commercial cellulases or brown rot fungal extracts, loaded at equal but low endoglucanase titers. Saccharification was then repeated for high-yield samples using full strength commercial cellulases. Overall, brown rot pretreatments enhanced yields up to threefold when using either cellulase preparation. In the best case, aspen degraded 2. weeks by G. trabeum yielded 72% glucose-from-cellulose, a 51% yield relative to original glucan. A follow-up trial with more frequent harvests showed similar patterns and demonstrated interplay between tissue modifications and saccharification. Hemicellulose and vanillic acid (G6) or vanillin (G4) lignin residues were good predictors of saccharification potential, the latter notable given lignin's potential active role in brown rot. Results show basic relationships over a brown rot time course and lend targets for controlling an applied bioconversion process.

Original language	English (US)
Pages (from-to)	147-154
Number of pages	8
Journal	Bioresource Technology
Volume	116
DOIs	https://doi.org/10.1016/j.biortech.2012.04.018
State	Published - Jul 2012

Bibliographical note

Funding Information:
We are grateful for funding through a U.S. Department of Energy (DOE) Biomass Initiative Grant, number GO18088 . We also acknowledge the input of Dr. Charles Abbas from Archer Daniel Midland (ADM) Corporation, Mr. Jake Tewalt of POET, and Mr. Justin Kaffenberger of the University of Minnesota.

Keywords

Bioconversion
Biodegradation
Deconstruction
White rot
Wood

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title = "Lignocellulose modifications by brown rot fungi and their effects, as pretreatments, on cellulolysis",

abstract = "Brown rot fungi Gloeophyllum trabeum and Postia placenta were used to degrade aspen, spruce, or corn stover over 16. weeks. Decayed residues were saccharified using commercial cellulases or brown rot fungal extracts, loaded at equal but low endoglucanase titers. Saccharification was then repeated for high-yield samples using full strength commercial cellulases. Overall, brown rot pretreatments enhanced yields up to threefold when using either cellulase preparation. In the best case, aspen degraded 2. weeks by G. trabeum yielded 72% glucose-from-cellulose, a 51% yield relative to original glucan. A follow-up trial with more frequent harvests showed similar patterns and demonstrated interplay between tissue modifications and saccharification. Hemicellulose and vanillic acid (G6) or vanillin (G4) lignin residues were good predictors of saccharification potential, the latter notable given lignin's potential active role in brown rot. Results show basic relationships over a brown rot time course and lend targets for controlling an applied bioconversion process.",

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note = "Funding Information: We are grateful for funding through a U.S. Department of Energy (DOE) Biomass Initiative Grant, number GO18088 . We also acknowledge the input of Dr. Charles Abbas from Archer Daniel Midland (ADM) Corporation, Mr. Jake Tewalt of POET, and Mr. Justin Kaffenberger of the University of Minnesota. ",

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AU - Ai, Jun

AU - Blanchette, Robert A.

AU - Duncan, Shona M.

AU - Filley, Timothy R.

AU - Tschirner, Ulrike W.

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N2 - Brown rot fungi Gloeophyllum trabeum and Postia placenta were used to degrade aspen, spruce, or corn stover over 16. weeks. Decayed residues were saccharified using commercial cellulases or brown rot fungal extracts, loaded at equal but low endoglucanase titers. Saccharification was then repeated for high-yield samples using full strength commercial cellulases. Overall, brown rot pretreatments enhanced yields up to threefold when using either cellulase preparation. In the best case, aspen degraded 2. weeks by G. trabeum yielded 72% glucose-from-cellulose, a 51% yield relative to original glucan. A follow-up trial with more frequent harvests showed similar patterns and demonstrated interplay between tissue modifications and saccharification. Hemicellulose and vanillic acid (G6) or vanillin (G4) lignin residues were good predictors of saccharification potential, the latter notable given lignin's potential active role in brown rot. Results show basic relationships over a brown rot time course and lend targets for controlling an applied bioconversion process.

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Lignocellulose modifications by brown rot fungi and their effects, as pretreatments, on cellulolysis

Abstract

Bibliographical note

Keywords

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