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Literature DB >> 28087936

Fungal Ligninolytic Enzymes and Their Applications.

Miia R Mäkelä¹, Erin L Bredeweg², Jon K Magnuson^3,4, Scott E Baker^2,3, Ronald P de Vries^1,5, Kristiina Hildén¹.

Abstract

The global push toward an efficient and economical biobased economy has driven research to develop more cost-effective applications for the entirety of plant biomass, including lignocellulosic crops. As discussed elsewhere (Karlsson M, Atanasova L, Funck Jensen D, Zeilinger S, in Heitman J et al. [ed], Tuberculosis and the Tubercle Bacillus, 2nd ed, in press), significant progress has been made in the use of polysaccharide fractions from lignocellulose, cellulose, and various hemicellulose types. However, developing processes for use of the lignin fraction has been more challenging. In this chapter, we discuss characteristics of lignolytic enzymes and the fungi that produce them as well as potential and current uses of lignin-derived products.

Entities: Chemical Disease Species

Mesh：

Substances：
Lignin
Oxidoreductases

Year: 2016 PMID： 28087936 DOI： 10.1128/microbiolspec.FUNK-0017-2016

Source DB: PubMed Journal: Microbiol Spectr ISSN： 2165-0497

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Cited

6 in total

1. Induction of Genes Encoding Plant Cell Wall-Degrading Carbohydrate-Active Enzymes by Lignocellulose-Derived Monosaccharides and Cellobiose in the White-Rot Fungus Dichomitus squalens.

Authors: Sara Casado López; Mao Peng; Tedros Yonatan Issak; Paul Daly; Ronald P de Vries; Miia R Mäkelä
Journal: Appl Environ Microbiol Date: 2018-05-17 Impact factor: 4.792

2. Lignocellulose binding of a Cel5A-RtCBM11 chimera with enhanced β-glucanase activity monitored by electron paramagnetic resonance.

Authors: Raquel Fonseca-Maldonado; Luana P Meleiro; Luís F S Mendes; Luana F Alves; Sibeli Carli; Lucas D Morero; Luis G M Basso; Antonio J Costa-Filho; Richard J Ward
Journal: Biotechnol Biofuels Date: 2017-11-14 Impact factor: 6.040

Fungal Ligninolytic Enzymes and Their Applications.

1. Induction of Genes Encoding Plant Cell Wall-Degrading Carbohydrate-Active Enzymes by Lignocellulose-Derived Monosaccharides and Cellobiose in the White-Rot Fungus Dichomitus squalens.

2. Lignocellulose binding of a Cel5A-RtCBM11 chimera with enhanced β-glucanase activity monitored by electron paramagnetic resonance.

3. MopA, the Mn Oxidizing Protein From Erythrobacter sp. SD-21, Requires Heme and NAD⁺ for Mn(II) Oxidation.

Review 4. Genome-based engineering of ligninolytic enzymes in fungi.

5. Lignin Degradation and Its Use in Signaling Development by the Coprophilous Ascomycete Podospora anserina.

Review 6. Depolymerization and conversion of lignin to value-added bioproducts by microbial and enzymatic catalysis.

Fungal Ligninolytic Enzymes and Their Applications.

1. Induction of Genes Encoding Plant Cell Wall-Degrading Carbohydrate-Active Enzymes by Lignocellulose-Derived Monosaccharides and Cellobiose in the White-Rot Fungus Dichomitus squalens.

2. Lignocellulose binding of a Cel5A-RtCBM11 chimera with enhanced β-glucanase activity monitored by electron paramagnetic resonance.

3. MopA, the Mn Oxidizing Protein From Erythrobacter sp. SD-21, Requires Heme and NAD+ for Mn(II) Oxidation.

Review 4. Genome-based engineering of ligninolytic enzymes in fungi.

5. Lignin Degradation and Its Use in Signaling Development by the Coprophilous Ascomycete Podospora anserina.

Review 6. Depolymerization and conversion of lignin to value-added bioproducts by microbial and enzymatic catalysis.

3. MopA, the Mn Oxidizing Protein From Erythrobacter sp. SD-21, Requires Heme and NAD⁺ for Mn(II) Oxidation.