Chemical characterization and in vitro fermentation of Brassica straw treated with the aerobic fungus, Trametes versicolor

Brassica napus straw (BNS) was either not treated or was treated with two strains of Trametes versicolor; 52J (wild type) or m4D (a cellobiose dehydrogenase-deficient mutant) with four treatments: (i) untreated control (C-BNS), (ii) 52J (B-52J), (iii) m4D (B-m4D) or (iv) m4D+glucose (B-m4Dg). Glucos...

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Published inCanadian journal of animal science Vol. 91; no. 4; pp. 695 - 702
Main Authors Ramirez-Bribiesca, J.E, Wang, Y, Jin, L, Canam, T, Town, J.R, Tsang, A, Dumonceaux, T.J, McAllister, T.A
Format Journal Article
LanguageEnglish
Published 01.12.2011
Subjects
Brassica napus
carbohydrate metabolism
Coriolus versicolor
ergosterol
fermentation
fungi
galactose
glucose
lignin
mannose
microbial biomass
mutants
neutral detergent fiber
rumen
rumen microorganisms
secondary productivity
sodium hydroxide
straw
volatile fatty acids
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Summary:Brassica napus straw (BNS) was either not treated or was treated with two strains of Trametes versicolor; 52J (wild type) or m4D (a cellobiose dehydrogenase-deficient mutant) with four treatments: (i) untreated control (C-BNS), (ii) 52J (B-52J), (iii) m4D (B-m4D) or (iv) m4D+glucose (B-m4Dg). Glucose was provided to encourage growth of the mutant strain. All treatments with T. versicolor decreased (P<0.05) neutral-detergent fibre and increased (P<0.05) protein and the concentration of lignin degradation products in straw. Ergosterol was highest (P<0.05) in straw treated with B-52J, suggesting it generated the most fungal biomass. Insoluble lignin was reduced (P<0.05) in straw treated with B-52J and B-m4D, but not with B-m4Dg. Mannose and xylose concentration were generally higher (P<0.05) in straw treated with fungi, whereas glucose and galactose were lower as compared with C-BNS. The four treatments above were subsequently assessed in rumen in vitro fermentations, along with BNS treated with 2 mL g-1 of 5 N NaOH. Concentrations of total volatile fatty acids after 24 and 48h were lower (P<0.05) in incubations that contained BNS treated with T. versicolor as compared with C-BNSor NaOH-treated BNS. Compared with C-BNS, in vitro dry matter disappearance and gas production were increased (P<0.05) by NaOH, but not by treatment with either strain of T. versicolor. Although treatment with T. versicolor did release more lignin degradation products, it did not appear to provide more degradable carbohydrate to in vitro rumen microbial populations, even when a mutant strain with compromised carbohydrate metabolism was utilized. Production of secondary compounds by the aerobic fungi may inhibit rumen microbial fermentation.
Bibliography:http://pubs.nrc-cnrc.gc.ca/aic-journals/cjas.html
ISSN:0008-3984
1918-1825
DOI:10.1139/CJAS2011-067