Your search keyword '"Ludwig R"' showing total 20 results

1. Mutational dissection of a hole hopping route in a lytic polysaccharide monooxygenase (LPMO).

Author

Ayuso-Fernández I, Emrich-Mills TZ, Haak J, Golten O, Hall KR, Schwaiger L, Moe TS, Stepnov AA, Ludwig R, Cutsail Iii GE, Sørlie M, Kjendseth Røhr Å, and Eijsink VGH

Subjects

Catalytic Domain, Tryptophan metabolism, Polysaccharides metabolism, Mutation, Oxidative Stress, Tyrosine metabolism, Models, Molecular, Histidine metabolism, Histidine genetics, Mixed Function Oxygenases metabolism, Mixed Function Oxygenases genetics, Mixed Function Oxygenases chemistry, Oxidation-Reduction, Bacterial Proteins metabolism, Bacterial Proteins genetics, Bacterial Proteins chemistry

Abstract

Oxidoreductases have evolved tyrosine/tryptophan pathways that channel highly oxidizing holes away from the active site to avoid damage. Here we dissect such a pathway in a bacterial LPMO, member of a widespread family of C-H bond activating enzymes with outstanding industrial potential. We show that a strictly conserved tryptophan is critical for radical formation and hole transference and that holes traverse the protein to reach a tyrosine-histidine pair in the protein's surface. Real-time monitoring of radical formation reveals a clear correlation between the efficiency of hole transference and enzyme performance under oxidative stress. Residues involved in this pathway vary considerably between natural LPMOs, which could reflect adaptation to different ecological niches. Importantly, we show that enzyme activity is increased in a variant with slower radical transference, providing experimental evidence for a previously postulated trade-off between activity and redox robustness., (© 2024. The Author(s).)

Published

2024

2. Continuous photometric activity assays for lytic polysaccharide monooxygenase-Critical assessment and practical considerations.

Author

Schwaiger L, Zenone A, Csarman F, and Ludwig R

Subjects

Cellulose, Oxidation-Reduction, Oxidoreductases metabolism, Mixed Function Oxygenases metabolism, Polysaccharides metabolism

Abstract

Lytic polysaccharide monooxygenase (LPMO) is a monocopper-dependent enzyme that cleaves glycosidic bonds by using an oxidative mechanism. In nature, they act in concert with cellobiohydrolases to facilitate the efficient degradation of lignocellulosic biomass. After more than a decade of LPMO research, it has become evident that LPMOs are abundant in all domains of life and fulfill a diverse range of biological functions. Independent of their biological function and the preferred polysaccharide substrate, studying and characterizing LPMOs is tedious and so far mostly relied on the discontinuous analysis of the solubilized reaction products by HPLC/MS-based methods. In the absence of appropriate substrates, LPMOs can engage in two off-pathway reactions, i.e., an oxidase and a peroxidase-like activity. These futile reactions have been exploited to set up easy-to-use continuous spectroscopic assays. As the natural substrates of newly discovered LPMOs are often unknown, widely applicable, simple, reliable, and robust spectroscopic assays are required to monitor LPMO expression and to perform initial biochemical characterizations, e.g., thermal stability measurements. Here we provide detailed descriptions and practical protocols to perform continuous photometric assays using either 2,6-dimethoxyphenol (2,6-DMP) or hydrocoerulignone as colorimetric substrates as a broadly applicable assay for a range of LPMOs. In addition, a turbidimetric measurement is described as the currently only method available to continuously monitor LPMOs acting on amorphous cellulose., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2023

3. Investigating lytic polysaccharide monooxygenase-assisted wood cell wall degradation with microsensors.

Author

Chang H, Gacias Amengual N, Botz A, Schwaiger L, Kracher D, Scheiblbrandner S, Csarman F, and Ludwig R

Subjects

Cellulose 1,4-beta-Cellobiosidase, Hydrogen Peroxide metabolism, Fungal Proteins metabolism, Polysaccharides metabolism, Oxidoreductases, Cell Wall metabolism, Glucose, Mixed Function Oxygenases metabolism, Wood metabolism

Abstract

Lytic polysaccharide monooxygenase (LPMO) supports biomass hydrolysis by increasing saccharification efficiency and rate. Recent studies demonstrate that H 2 O 2 rather than O 2 is the cosubstrate of the LPMO-catalyzed depolymerization of polysaccharides. Some studies have questioned the physiological relevance of the H 2 O 2 -based mechanism for plant cell wall degradation. This study reports the localized and time-resolved determination of LPMO activity on poplar wood cell walls by measuring the H 2 O 2 concentration in their vicinity with a piezo-controlled H 2 O 2 microsensor. The investigated Neurospora crassa LPMO binds to the inner cell wall layer and consumes enzymatically generated H 2 O 2 . The results point towards a high catalytic efficiency of LPMO at a low H 2 O 2 concentration that auxiliary oxidoreductases in fungal secretomes can easily generate. Measurements with a glucose microbiosensor additionally demonstrate that LPMO promotes cellobiohydrolase activity on wood cell walls and plays a synergistic role in the fungal extracellular catabolism and in industrial biomass degradation., (© 2022. The Author(s).)

Published

2022

4. Application of Causality Modelling for Prediction of Molecular Properties for Textile Dyes Degradation by LPMO.

Author

Rezić I, Kracher D, Oros D, Mujadžić S, Anđelini M, Kurtanjek Ž, Ludwig R, and Rezić T

Subjects

Azo Compounds, Biodegradation, Environmental, Coloring Agents, Models, Theoretical, Polysaccharides metabolism, Textile Industry, Textiles, Water, Mixed Function Oxygenases metabolism, Wastewater chemistry

Abstract

The textile industry is one of the largest water-polluting industries in the world. Due to an increased application of chromophores and a more frequent presence in wastewaters, the need for an ecologically favorable dye degradation process emerged. To predict the decolorization rate of textile dyes with Lytic polysaccharide monooxygenase (LPMO), we developed, validated, and utilized the molecular descriptor structural causality model (SCM) based on the decision tree algorithm (DTM). Combining mathematical models and theories with decolorization experiments, we have elucidated the most important molecular properties of the dyes and confirm the accuracy of SCM model results. Besides the potential utilization of the developed model in the treatment of textile dye-containing wastewater, the model is a good base for the prediction of the molecular properties of the molecule. This is important for selecting chromophores as the reagents in determining LPMO activities. Dyes with azo- or triarylmethane groups are good candidates for colorimetric LPMO assays and the determination of LPMO activity. An adequate methodology for the LPMO activity determination is an important step in the characterization of LPMO properties. Therefore, the SCM/DTM model validated with the 59 dyes molecules is a powerful tool in the selection of adequate chromophores as reagents in the LPMO activity determination and it could reduce experimentation in the screening experiments.

Published

2022

5. Regioselective C4 and C6 Double Oxidation of Cellulose by Lytic Polysaccharide Monooxygenases.

Author

Sun P, Laurent CVFP, Boerkamp VJP, van Erven G, Ludwig R, van Berkel WJH, and Kabel MA

Subjects

Oligosaccharides, Oxidation-Reduction, Polysaccharides, Cellulose metabolism, Mixed Function Oxygenases metabolism

Abstract

Lytic polysaccharide monooxygenases (LPMOs) play a key role in enzymatic degradation of hard-to-convert polysaccharides, such as chitin and cellulose. It is widely accepted that LPMOs catalyze a single regioselective oxidation of the C1 or C4 carbon of a glycosidic linkage, after which the destabilized linkage breaks. Here, a series of novel C4/C6 double oxidized cello-oligosaccharides was discovered. Products were characterized, aided by sodium borodeuteride reduction and hydrophilic interaction chromatography coupled to mass spectrometric analysis. The C4/C6 double oxidized products were generated by C4 and C1/C4 oxidizing LPMOs, but not by C1 oxidizing ones. By performing incubation and reduction in H 2 18 O, it was confirmed that the C6 gem-diol structure resulted from oxygenation, although oxidation to a C6 aldehyde, followed by hydration to the C6 gem-diol, could not be excluded. These findings can be extended to how the reactive LPMO-cosubstrate complex is positioned towards the substrate., (© 2021 The Authors. ChemSusChem published by Wiley-VCH GmbH.)

Published

2022

6. Lytic Polysaccharide Monooxygenase from Talaromyces amestolkiae with an Enigmatic Linker-like Region: The Role of This Enzyme on Cellulose Saccharification.

Author

Méndez-Líter JA, Ayuso-Fernández I, Csarman F, de Eugenio LI, Míguez N, Plou FJ, Prieto A, Ludwig R, and Martínez MJ

Subjects

Amino Acid Sequence, Cellulose chemistry, Enzyme Stability, Fungal Proteins chemistry, Mixed Function Oxygenases chemistry, Models, Molecular, Protein Conformation, Sequence Alignment, Substrate Specificity, Talaromyces chemistry, Talaromyces enzymology, Cellulose metabolism, Fungal Proteins metabolism, Mixed Function Oxygenases metabolism, Talaromyces metabolism

Abstract

The first lytic polysaccharide monooxygenase (LPMO) detected in the genome of the widespread ascomycete Talaromyces amestolkiae (TamAA9A) has been successfully expressed in Pichia pastoris and characterized. Molecular modeling of TamAA9A showed a structure similar to those from other AA9 LPMOs. Although fungal LPMOs belonging to the genera Penicillium or Talaromyces have not been analyzed in terms of regioselectivity, phylogenetic analyses suggested C1/C4 oxidation which was confirmed by HPAEC. To ascertain the function of a C-terminal linker-like region present in the wild-type sequence of the LPMO, two variants of the wild-type enzyme, one without this sequence and one with an additional C-terminal carbohydrate binding domain (CBM), were designed. The three enzymes (native, without linker and chimeric variant with a CBM) were purified in two chromatographic steps and were thermostable and active in the presence of H 2 O 2 . The transition midpoint temperature of the wild-type LPMO (Tm = 67.7 °C) and its variant with only the catalytic domain (Tm = 67.6 °C) showed the highest thermostability, whereas the presence of a CBM reduced it (Tm = 57.8 °C) and indicates an adverse effect on the enzyme structure. Besides, the potential of the different T. amestolkiae LPMO variants for their application in the saccharification of cellulosic and lignocellulosic materials was corroborated.

Published

2021

7. Insights into the H 2 O 2 -driven catalytic mechanism of fungal lytic polysaccharide monooxygenases.

Author

Hedison TM, Breslmayr E, Shanmugam M, Karnpakdee K, Heyes DJ, Green AP, Ludwig R, Scrutton NS, and Kracher D

Subjects

Biocatalysis, Cellulose metabolism, Electron Spin Resonance Spectroscopy methods, Fungal Proteins genetics, Glucans metabolism, Mixed Function Oxygenases genetics, Neurospora crassa genetics, Oxidation-Reduction, Polysaccharides metabolism, Protein Binding, Recombinant Proteins metabolism, Spectrophotometry methods, Substrate Specificity, Xylans metabolism, Fungal Polysaccharides metabolism, Fungal Proteins metabolism, Hydrogen Peroxide metabolism, Mixed Function Oxygenases metabolism, Neurospora crassa enzymology

Abstract

Fungal lytic polysaccharide monooxygenases (LPMOs) depolymerise crystalline cellulose and hemicellulose, supporting the utilisation of lignocellulosic biomass as a feedstock for biorefinery and biomanufacturing processes. Recent investigations have shown that H 2 O 2 is the most efficient cosubstrate for LPMOs. Understanding the reaction mechanism of LPMOs with H 2 O 2 is therefore of importance for their use in biotechnological settings. Here, we have employed a variety of spectroscopic and biochemical approaches to probe the reaction of the fungal LPMO9C from N. crassa using H 2 O 2 as a cosubstrate and xyloglucan as a polysaccharide substrate. We show that a single 'priming' electron transfer reaction from the cellobiose dehydrogenase partner protein supports up to 20 H 2 O 2 -driven catalytic cycles of a fungal LPMO. Using rapid mixing stopped-flow spectroscopy, alongside electron paramagnetic resonance and UV-Vis spectroscopy, we reveal how H 2 O 2 and xyloglucan interact with the enzyme and investigate transient species that form uncoupled pathways of NcLPMO9C. Our study shows how the H 2 O 2 cosubstrate supports fungal LPMO catalysis and leaves the enzyme in the reduced Cu + state following a single enzyme turnover, thus preventing the need for external protons and electrons from reducing agents or cellobiose dehydrogenase and supporting the binding of H 2 O 2 for further catalytic steps. We observe that the presence of the substrate xyloglucan stabilises the Cu + state of LPMOs, which may prevent the formation of uncoupled side reactions., (© 2021 The Authors. The FEBS Journal published by John Wiley & Sons Ltd on behalf of Federation of European Biochemical Societies.)

Published

2021

8. Polysaccharide oxidation by lytic polysaccharide monooxygenase is enhanced by engineered cellobiose dehydrogenase.

Author

Kracher D, Forsberg Z, Bissaro B, Gangl S, Preims M, Sygmund C, Eijsink VGH, and Ludwig R

Subjects

Cellulose metabolism, Hydrogen Peroxide metabolism, Carbohydrate Dehydrogenases metabolism, Mixed Function Oxygenases metabolism, Polysaccharides metabolism

Abstract

The catalytic function of lytic polysaccharide monooxygenases (LPMOs) to cleave and decrystallize recalcitrant polysaccharides put these enzymes in the spotlight of fundamental and applied research. Here we demonstrate that the demand of LPMO for an electron donor and an oxygen species as cosubstrate can be fulfilled by a single auxiliary enzyme: an engineered fungal cellobiose dehydrogenase (CDH) with increased oxidase activity. The engineered CDH was about 30 times more efficient in driving the LPMO reaction due to its 27 time increased production of H 2 O 2 acting as a cosubstrate for LPMO. Transient kinetic measurements confirmed that intra- and intermolecular electron transfer rates of the engineered CDH were similar to the wild-type CDH, meaning that the mutations had not compromised CDH's role as an electron donor. These results support the notion of H 2 O 2 -driven LPMO activity and shed new light on the role of CDH in activating LPMOs. Importantly, the results also demonstrate that the use of the engineered CDH results in fast and steady LPMO reactions with CDH-generated H 2 O 2 as a cosubstrate, which may provide new opportunities to employ LPMOs in biomass hydrolysis to generate fuels and chemicals., (© 2019 The Authors. The FEBS Journal published by John Wiley & Sons Ltd on behalf of Federation of European Biochemical Societies.)

Published

2020

9. Structural Dynamics of Lytic Polysaccharide Monooxygenase during Catalysis.

Author

Filandr F, Kavan D, Kracher D, Laurent CVFP, Ludwig R, Man P, and Halada P

Subjects

Catalysis, Catalytic Domain, Cellulose chemistry, Fungal Proteins chemistry, Hydrogen-Ion Concentration, Lignin chemistry, Mass Spectrometry, Oxidative Stress, Oxidoreductases chemistry, Protein Binding, Protein Conformation, Reactive Oxygen Species chemistry, Spectrometry, Mass, Electrospray Ionization, Substrate Specificity, Copper chemistry, Mixed Function Oxygenases chemistry, Neurospora crassa enzymology, Oxygen chemistry, Polysaccharides chemistry

Abstract

Lytic polysaccharide monooxygenases (LPMOs) are industrially important oxidoreductases employed in lignocellulose saccharification. Using advanced time-resolved mass spectrometric techniques, we elucidated the structural determinants for substrate-mediated stabilization of the fungal LPMO9C from Neurospora crassa during catalysis. LPMOs require a reduction in the active-site copper for catalytic activity. We show that copper reduction in Nc LPMO9C leads to structural rearrangements and compaction around the active site. However, longer exposure to the reducing agent ascorbic acid also initiated an uncoupling reaction of the bound oxygen species, leading to oxidative damage, partial unfolding, and even fragmentation of Nc LPMO9C. Interestingly, no changes in the hydrogen/deuterium exchange rate were detected upon incubation of oxidized or reduced LPMO with crystalline cellulose, indicating that the LPMO-substrate interactions are mainly side-chain mediated and neither affect intraprotein hydrogen bonding nor induce significant shielding of the protein surface. On the other hand, we observed a protective effect of the substrate, which slowed down the autooxidative damage induced by the uncoupling reaction. These observations further complement the picture of structural changes during LPMO catalysis., Competing Interests: The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

Published

2020

10. Influence of Lytic Polysaccharide Monooxygenase Active Site Segments on Activity and Affinity.

Author

Laurent CVFP, Sun P, Scheiblbrandner S, Csarman F, Cannazza P, Frommhagen M, van Berkel WJH, Oostenbrink C, Kabel MA, and Ludwig R

Subjects

Binding Sites, Carboxymethylcellulose Sodium metabolism, Catalytic Domain, Cellulose metabolism, Fungal Proteins chemistry, Fungal Proteins genetics, Fungal Proteins metabolism, Glucans metabolism, Mixed Function Oxygenases genetics, Neurospora crassa genetics, Sequence Deletion, Surface Plasmon Resonance, Xylans metabolism, Mixed Function Oxygenases chemistry, Mixed Function Oxygenases metabolism, Neurospora crassa enzymology

Abstract

In past years, new lytic polysaccharide monooxygenases (LPMOs) have been discovered as distinct in their substrate specificity. Their unconventional, surface-exposed catalytic sites determine their enzymatic activities, while binding sites govern substrate recognition and regioselectivity. An additional factor influencing activity is the presence or absence of a family 1 carbohydrate binding module (CBM1) connected via a linker to the C-terminus of the LPMO. This study investigates the changes in activity induced by shortening the second active site segment (Seg2) or removing the CBM1 from Neurospora crassa LPMO9C. Nc LPMO9C and generated variants have been tested on regenerated amorphous cellulose (RAC), carboxymethyl cellulose (CMC) and xyloglucan (XG) using activity assays, conversion experiments and surface plasmon resonance spectroscopy. The absence of CBM1 reduced the binding affinity and activity of Nc LPMO9C, but did not affect its regioselectivity. The linker was found important for the thermal stability of Nc LPMO9C and the CBM1 is necessary for efficient binding to RAC. Wild-type Nc LPMO9C exhibited the highest activity and strongest substrate binding. Shortening of Seg2 greatly reduced the activity on RAC and CMC and completely abolished the activity on XG. This demonstrates that Seg2 is indispensable for substrate recognition and the formation of productive enzyme-substrate complexes.

Published

2019

11. Interaction between Cellobiose Dehydrogenase and Lytic Polysaccharide Monooxygenase.

Author

Laurent CVFP, Breslmayr E, Tunega D, Ludwig R, and Oostenbrink C

Subjects

Catalytic Domain, Fungal Proteins chemistry, Fungal Proteins metabolism, Molecular Docking Simulation, Molecular Dynamics Simulation, Neurospora crassa enzymology, Protein Interaction Domains and Motifs, Carbohydrate Dehydrogenases chemistry, Carbohydrate Dehydrogenases metabolism, Mixed Function Oxygenases chemistry, Mixed Function Oxygenases metabolism

Abstract

Lytic polysaccharide monooxygenases (LPMOs) are ubiquitous oxidoreductases, facilitating the degradation of polymeric carbohydrates in biomass. Cellobiose dehydrogenase (CDH) is a biologically relevant electron donor in this process, with the electrons resulting from cellobiose oxidation being shuttled from the CDH dehydrogenase domain to its cytochrome domain and then to the LPMO catalytic site. In this work, we investigate the interaction of four Neurospora crassa LPMOs and five CDH cytochrome domains from different species using computational methods. We used HADDOCK to perform protein-protein docking experiments on all 20 combinations and subsequently to select four complexes for extensive molecular dynamics simulations. The potential of mean force is computed for a rotation of the cytochrome domain relative to LPMO. We find that the LPMO loops are largely responsible for the preferred orientations of the cytochrome domains. This leads us to postulate a hybrid version of NcLPMO9F, with exchanged loops and predicted altered cytochrome binding preferences for this variant. Our work provides insight into the possible mechanisms of electron transfer between the two protein systems, in agreement with and complementary to previously published experimental data.

Published

2019

12. Multipoint Precision Binding of Substrate Protects Lytic Polysaccharide Monooxygenases from Self-Destructive Off-Pathway Processes.

Author

Loose JSM, Arntzen MØ, Bissaro B, Ludwig R, Eijsink VGH, and Vaaje-Kolstad G

Subjects

Bacterial Proteins chemistry, Bacterial Proteins genetics, Binding Sites, Catalytic Domain, Chitin metabolism, Copper chemistry, Copper metabolism, Mixed Function Oxygenases chemistry, Mixed Function Oxygenases genetics, Models, Molecular, Mutagenesis, Site-Directed, Oxidation-Reduction, Protein Binding, Serratia Infections microbiology, Serratia marcescens chemistry, Serratia marcescens genetics, Substrate Specificity, Bacterial Proteins metabolism, Mixed Function Oxygenases metabolism, Polysaccharides metabolism, Serratia marcescens metabolism

Abstract

Lytic polysaccharide monooxygenases (LPMOs) play a crucial role in the degradation of polysaccharides in biomass by catalyzing powerful oxidative chemistry using only a single copper ion as a cofactor. Despite the natural abundance and importance of these powerful monocopper enzymes, the structural determinants of their functionality have remained largely unknown. We have used site-directed mutagenesis to probe the roles of 13 conserved amino acids located on the flat substrate-binding surface of CBP21, a chitin-active family AA10 LPMO from Serratia marcescens, also known as SmLPMO10A. Single mutations of residues that do not interact with the catalytic copper site, but rather are involved in substrate binding had remarkably strong effects on overall enzyme performance. Analysis of product formation over time showed that these mutations primarily affected enzyme stability. Investigation of protein integrity using proteomics technologies showed that loss of activity was caused by oxidation of essential residues in the enzyme active site. For most enzyme variants, reduced enzyme stability correlated with a reduced level of binding to chitin, suggesting that adhesion to the substrate prevents oxidative off-pathway processes that lead to enzyme inactivation. Thus, the extended and highly evolvable surfaces of LPMOs are tailored for precise multipoint substrate binding, which provides the confinement that is needed to harness and control the remarkable oxidative power of these enzymes. These findings are important for the optimized industrial use of LPMOs as well as the design of LPMO-inspired catalysts.

Published

2018

13. Active-site copper reduction promotes substrate binding of fungal lytic polysaccharide monooxygenase and reduces stability.

Author

Kracher D, Andlar M, Furtmüller PG, and Ludwig R

Subjects

Catalytic Domain, Copper metabolism, Fungal Proteins genetics, Mixed Function Oxygenases genetics, Neurospora crassa genetics, Cellulose chemistry, Copper chemistry, Fungal Proteins chemistry, Mixed Function Oxygenases chemistry, Neurospora crassa enzymology

Abstract

Lytic polysaccharide monooxygenases (LPMOs) are a class of copper-containing enzymes that oxidatively degrade insoluble plant polysaccharides and soluble oligosaccharides. Upon reductive activation, they cleave the substrate and promote biomass degradation by hydrolytic enzymes. In this study, we employed LPMO9C from Neurospora crassa , which is active toward cellulose and soluble β-glucans, to study the enzyme-substrate interaction and thermal stability. Binding studies showed that the reduction of the mononuclear active-site copper by ascorbic acid increased the affinity and the maximum binding capacity of LPMO for cellulose. The reduced redox state of the active-site copper and not the subsequent formation of the activated oxygen species increased the affinity toward cellulose. The lower affinity of oxidized LPMO could support its desorption after catalysis and allow hydrolases to access the cleavage site. It also suggests that the copper reduction is not necessarily performed in the substrate-bound state of LPMO. Differential scanning fluorimetry showed a stabilizing effect of the substrates cellulose and xyloglucan on the apparent transition midpoint temperature of the reduced, catalytically active enzyme. Oxidative auto-inactivation and destabilization were observed in the absence of a suitable substrate. Our data reveal the determinants of LPMO stability under turnover and non-turnover conditions and indicate that the reduction of the active-site copper initiates substrate binding., (© 2018 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2018

14. Activation of bacterial lytic polysaccharide monooxygenases with cellobiose dehydrogenase.

Author

Loose JS, Forsberg Z, Kracher D, Scheiblbrandner S, Ludwig R, Eijsink VG, and Vaaje-Kolstad G

Subjects

Chitin chemistry, Lactose chemistry, Oxidation-Reduction, Bacteria enzymology, Bacterial Proteins chemistry, Carbohydrate Dehydrogenases chemistry, Fungal Proteins chemistry, Mixed Function Oxygenases chemistry, Sordariales enzymology

Abstract

Lytic polysaccharide monooxygenases (LPMOs) represent a recent addition to the carbohydrate-active enzymes and are classified as auxiliary activity (AA) families 9, 10, 11, and 13. LPMOs are crucial for effective degradation of recalcitrant polysaccharides like cellulose or chitin. These enzymes are copper-dependent and utilize a redox mechanism to cleave glycosidic bonds that is dependent on molecular oxygen and an external electron donor. The electrons can be provided by various sources, such as chemical compounds (e.g., ascorbate) or by enzymes (e.g., cellobiose dehydrogenases, CDHs, from fungi). Here, we demonstrate that a fungal CDH from Myriococcum thermophilum (MtCDH), can act as an electron donor for bacterial family AA10 LPMOs. We show that employing an enzyme as electron donor is advantageous since this enables a kinetically controlled supply of electrons to the LPMO. The rate of chitin oxidation by CBP21 was equal to that of cosubstrate (lactose) oxidation by MtCDH, verifying the usage of two electrons in the LPMO catalytic mechanism. Furthermore, since lactose oxidation correlates directly with the rate of LPMO catalysis, a method for indirect determination of LPMO activity is implicated. Finally, the one electron reduction of the CBP21 active site copper by MtCDH was determined to be substantially faster than chitin oxidation by the LPMO. Overall, MtCDH seems to be a universal electron donor for both bacterial and fungal LPMOs, indicating that their electron transfer mechanisms are similar., (© 2016 The Protein Society.)

Published

2016

15. Extracellular electron transfer systems fuel cellulose oxidative degradation.

Author

Kracher D, Scheiblbrandner S, Felice AK, Breslmayr E, Preims M, Ludwicka K, Haltrich D, Eijsink VG, and Ludwig R

Subjects

Biocatalysis, Electron Transport, Fungal Proteins genetics, Fungi genetics, Genome, Fungal, Mixed Function Oxygenases genetics, Oxidation-Reduction, Fungal Proteins chemistry, Fungi enzymology, Lignin chemistry, Mixed Function Oxygenases chemistry

Abstract

Ninety percent of lignocellulose-degrading fungi contain genes encoding lytic polysaccharide monooxygenases (LPMOs). These enzymes catalyze the initial oxidative cleavage of recalcitrant polysaccharides after activation by an electron donor. Understanding the source of electrons is fundamental to fungal physiology and will also help with the exploitation of LPMOs for biomass processing. Using genome data and biochemical methods, we characterized and compared different extracellular electron sources for LPMOs: cellobiose dehydrogenase, phenols procured from plant biomass or produced by fungi, and glucose-methanol-choline oxidoreductases that regenerate LPMO-reducing diphenols. Our data demonstrate that all three of these electron transfer systems are functional and that their relative importance during cellulose degradation depends on fungal lifestyle. The availability of extracellular electron donors is required to activate fungal oxidative attack on polysaccharides., (Copyright © 2016, American Association for the Advancement of Science.)

Published

2016

16. Interactions of a fungal lytic polysaccharide monooxygenase with β-glucan substrates and cellobiose dehydrogenase.

Author

Courtade G, Wimmer R, Røhr ÅK, Preims M, Felice AK, Dimarogona M, Vaaje-Kolstad G, Sørlie M, Sandgren M, Ludwig R, Eijsink VG, and Aachmann FL

Subjects

Binding Sites, Carbohydrate Dehydrogenases genetics, Copper chemistry, Fungal Proteins genetics, Mixed Function Oxygenases genetics, Neurospora crassa genetics, Nuclear Magnetic Resonance, Biomolecular, Substrate Specificity, Carbohydrate Dehydrogenases chemistry, Fungal Proteins chemistry, Mixed Function Oxygenases chemistry, Neurospora crassa enzymology

Abstract

Lytic polysaccharide monooxygenases (LPMOs) are copper-dependent enzymes that catalyze oxidative cleavage of glycosidic bonds using molecular oxygen and an external electron donor. We have used NMR and isothermal titration calorimetry (ITC) to study the interactions of a broad-specificity fungal LPMO, NcLPMO9C, with various substrates and with cellobiose dehydrogenase (CDH), a known natural supplier of electrons. The NMR studies revealed interactions with cellohexaose that center around the copper site. NMR studies with xyloglucans, i.e., branched β-glucans, showed an extended binding surface compared with cellohexaose, whereas ITC experiments showed slightly higher affinity and a different thermodynamic signature of binding. The ITC data also showed that although the copper ion alone hardly contributes to affinity, substrate binding is enhanced for metal-loaded enzymes that are supplied with cyanide, a mimic of O2 (-) Studies with CDH and its isolated heme b cytochrome domain unambiguously showed that the cytochrome domain of CDH interacts with the copper site of the LPMO and that substrate binding precludes interaction with CDH. Apart from providing insights into enzyme-substrate interactions in LPMOs, the present observations shed new light on possible mechanisms for electron supply during LPMO action.

Published

2016

17. Tandem-yeast expression system for engineering and producing unspecific peroxygenase.

Author

Molina-Espeja P, Ma S, Mate DM, Ludwig R, and Alcalde M

Subjects

Agrocybe genetics, Alcohol Oxidoreductases genetics, Fermentation, Fungal Proteins genetics, Genes, Fungal, Mixed Function Oxygenases genetics, Promoter Regions, Genetic genetics, Recombinant Fusion Proteins isolation & purification, Recombinant Fusion Proteins metabolism, Agrocybe enzymology, Directed Molecular Evolution methods, Fungal Proteins biosynthesis, Mixed Function Oxygenases biosynthesis, Pichia metabolism, Protein Engineering methods, Saccharomyces cerevisiae metabolism

Abstract

Unspecific peroxygenase (UPO) is a highly efficient biocatalyst with a peroxide dependent monooxygenase activity and many biotechnological applications, but the absence of suitable heterologous expression systems has precluded its use in different industrial settings. Recently, the UPO from Agrocybe aegerita was evolved for secretion and activity in Saccharomyces cerevisiae [8]. In the current work, we describe a tandem-yeast expression system for UPO engineering and large scale production. By harnessing the directed evolution process in S. cerevisiae, the beneficial mutations for secretion enabled Pichia pastoris to express the evolved UPO under the control of the methanol inducible alcohol oxidase 1 promoter. Whilst secretion levels were found similar for both yeasts in flask fermentation (∼8mg/L), the recombinant UPO from P. pastoris showed a 27-fold enhanced production in fed-batch fermentation (217mg/L). The P. pastoris UPO variant maintained similar biochemical properties of the S. cerevisiae counterpart in terms of catalytic constants, pH activity profiles and thermostability. Thus, this tandem-yeast expression system ensures the engineering of UPOs to use them in future industrial applications as well as large scale production., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

18. Cellulose surface degradation by a lytic polysaccharide monooxygenase and its effect on cellulase hydrolytic efficiency.

Author

Eibinger M, Ganner T, Bubner P, Rošker S, Kracher D, Haltrich D, Ludwig R, Plank H, and Nidetzky B

Subjects

Cellulase, Hydrolysis, Neurospora crassa enzymology, Oxidation-Reduction, Surface Properties, Cellulose chemistry, Fungal Proteins chemistry, Mixed Function Oxygenases chemistry

Abstract

Lytic polysaccharide monooxygenase (LPMO) represents a unique principle of oxidative degradation of recalcitrant insoluble polysaccharides. Used in combination with hydrolytic enzymes, LPMO appears to constitute a significant factor of the efficiency of enzymatic biomass depolymerization. LPMO activity on different cellulose substrates has been shown from the slow release of oxidized oligosaccharides into solution, but an immediate and direct demonstration of the enzyme action on the cellulose surface is lacking. Specificity of LPMO for degrading ordered crystalline and unordered amorphous cellulose material of the substrate surface is also unknown. We show by fluorescence dye adsorption analyzed with confocal laser scanning microscopy that a LPMO (from Neurospora crassa) introduces carboxyl groups primarily in surface-exposed crystalline areas of the cellulosic substrate. Using time-resolved in situ atomic force microscopy we further demonstrate that cellulose nano-fibrils exposed on the surface are degraded into shorter and thinner insoluble fragments. Also using atomic force microscopy, we show that prior action of LPMO enables cellulases to attack otherwise highly resistant crystalline substrate areas and that it promotes an overall faster and more complete surface degradation. Overall, this study reveals key characteristics of LPMO action on the cellulose surface and suggests the effects of substrate morphology on the synergy between LPMO and hydrolytic enzymes in cellulose depolymerization., (© 2014 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2014

19. Discovery of LPMO activity on hemicelluloses shows the importance of oxidative processes in plant cell wall degradation.

Author

Agger JW, Isaksen T, Várnai A, Vidal-Melgosa S, Willats WG, Ludwig R, Horn SJ, Eijsink VG, and Westereng B

Subjects

Arabidopsis cytology, Arabidopsis metabolism, Glucans chemistry, Glucans metabolism, Solanum lycopersicum cytology, Solanum lycopersicum metabolism, Mannans metabolism, Microarray Analysis, Oxidation-Reduction, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Substrate Specificity, Xylans chemistry, Xylans metabolism, beta-Glucans metabolism, Cell Wall metabolism, Mixed Function Oxygenases metabolism, Neurospora crassa enzymology, Plant Cells metabolism, Polysaccharides metabolism

Abstract

The recently discovered lytic polysaccharide monooxygenases (LPMOs) are known to carry out oxidative cleavage of glycoside bonds in chitin and cellulose, thus boosting the activity of well-known hydrolytic depolymerizing enzymes. Because biomass-degrading microorganisms tend to produce a plethora of LPMOs, and considering the complexity and copolymeric nature of the plant cell wall, it has been speculated that some LPMOs may act on other substrates, in particular the hemicelluloses that tether to cellulose microfibrils. We demonstrate that an LPMO from Neurospora crassa, NcLPMO9C, indeed degrades various hemicelluloses, in particular xyloglucan. This activity was discovered using a glycan microarray-based screening method for detection of substrate specificities of carbohydrate-active enzymes, and further explored using defined oligomeric hemicelluloses, isolated polymeric hemicelluloses and cell walls. Products generated by NcLPMO9C were analyzed using high performance anion exchange chromatography and multidimensional mass spectrometry. We show that NcLPMO9C generates oxidized products from a variety of substrates and that its product profile differs from those of hydrolytic enzymes acting on the same substrates. The enzyme particularly acts on the glucose backbone of xyloglucan, accepting various substitutions (xylose, galactose) in almost all positions. Because the attachment of xyloglucan to cellulose hampers depolymerization of the latter, it is possible that the beneficial effect of the LPMOs that are present in current commercial cellulase mixtures in part is due to hitherto undetected LPMO activities on recalcitrant hemicellulose structures.

Published

2014

20. A C4-oxidizing lytic polysaccharide monooxygenase cleaving both cellulose and cello-oligosaccharides.

Author

Isaksen T, Westereng B, Aachmann FL, Agger JW, Kracher D, Kittl R, Ludwig R, Haltrich D, Eijsink VG, and Horn SJ

Subjects

Carbon metabolism, Mass Spectrometry, Neurospora crassa metabolism, Oxidation-Reduction, Oxygen metabolism, Polysaccharides metabolism, Biofuels microbiology, Cellulose metabolism, Mixed Function Oxygenases metabolism, Neurospora crassa enzymology, Oligosaccharides metabolism

Abstract

Lignocellulosic biomass is a renewable resource that significantly can substitute fossil resources for the production of fuels, chemicals, and materials. Efficient saccharification of this biomass to fermentable sugars will be a key technology in future biorefineries. Traditionally, saccharification was thought to be accomplished by mixtures of hydrolytic enzymes. However, recently it has been shown that lytic polysaccharide monooxygenases (LPMOs) contribute to this process by catalyzing oxidative cleavage of insoluble polysaccharides utilizing a mechanism involving molecular oxygen and an electron donor. These enzymes thus represent novel tools for the saccharification of plant biomass. Most characterized LPMOs, including all reported bacterial LPMOs, form aldonic acids, i.e., products oxidized in the C1 position of the terminal sugar. Oxidation at other positions has been observed, and there has been some debate concerning the nature of this position (C4 or C6). In this study, we have characterized an LPMO from Neurospora crassa (NcLPMO9C; also known as NCU02916 and NcGH61-3). Remarkably, and in contrast to all previously characterized LPMOs, which are active only on polysaccharides, NcLPMO9C is able to cleave soluble cello-oligosaccharides as short as a tetramer, a property that allowed detailed product analysis. Using mass spectrometry and NMR, we show that the cello-oligosaccharide products released by this enzyme contain a C4 gemdiol/keto group at the nonreducing end.

Published

2014