Rui M. F. Bezerra scite author profile

a b s t r a c tWheat straw was submitted to a pre-treatment by the basidiomycetous fungi Euc-1 and Irpex lacteus, aiming to improve the accessibility of cellulose towards enzymatic hydrolysis via previous selective bio-delignification. This allowed the increase of substrate saccharification nearly four and three times while applying the basidiomycetes Euc-1 and I. lacteus, respectively. The cellulose/lignin ratio increased from 2.7 in the untreated wheat straw to 5.9 and 4.6 after the bio-treatment by the basidiomycetes Euc-1 and I. lacteus, respectively, thus evidencing the highly selective lignin biodegradation. The enzymatic profile of both fungi upon bio-treatment of wheat straw have been assessed including laccase, manganese-dependent peroxidase, lignin peroxidase, carboxymethylcellulase, xylanase, avicelase and feruloyl esterase activities. The difference in efficiency and selectivity of delignification within the two fungi treatments was interpreted in terms of specific lignolytic enzyme profiles and moderate xylanase and cellulolytic activities.

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Influence of ligninolytic enzymes on straw saccharification during fungal pretreatment

Pinto

Dias

Fraga

et al. 2012

Bioresource Technology

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Discrimination Among Eight Modified Michaelis-Menten Kinetics Models of Cellulose Hydrolysis With a Large Range of Substrate/Enzyme Ratios: Inhibition by Cellobiose

Bezerra

Dias

2004

ABAB

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The kinetics of exoglucanase (Cel7A) from Trichoderma reesei was investigated in the presence of cellobiose and 24 different enzyme/Avicel ratios for 47 h, in order to establish which of the eight available kinetic models best explained the factors involved. The heterogeneous catalysis was studied and the kinetic parameters were estimated employing integrated forms of Michaelis-Menten equations through the use of nonlinear least squares. It was found that cellulose hydrolysis follows a model that takes into account competitive inhibition by cellobiose (final product) with the following parameters: Km = 3.8 mM, Kic = 0.041 mM, kcat = 2 h-1 (5.6 x 10-4 s-1). Other models, such as mixed type inhibition and those incorporating improvements concerning inhibition by substrate and parabolic inhibition, increased the modulation performance very slightly. The results support the hypothesis that nonproductive enzyme substrate complexes, parabolic inhibition, and enzyme inactivation (Selwyn test) are not the principal constraints in enzymatic cellulose hydrolysis. Under our conditions, the increment in hydrolysis was not significant for substrate/enzyme ratios <6.5.

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Rui M. F. Bezerra

Modification of wheat straw lignin by solid state fermentation with white-rot fungi

Effect of enzyme extracts isolated from white-rot fungi on chemical composition and in vitro digestibility of wheat straw

Enzymatic saccharification of biologically pre-treated wheat straw with white-rot fungi

Influence of ligninolytic enzymes on straw saccharification during fungal pretreatment

Discrimination Among Eight Modified Michaelis-Menten Kinetics Models of Cellulose Hydrolysis With a Large Range of Substrate/Enzyme Ratios: Inhibition by Cellobiose

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