Your search keyword '"Morten Sørlie"' showing total 84 results

1. Reductants fuel lytic polysaccharide monooxygenase activity in a pH‐dependent manner

Author

Ole Golten, Iván Ayuso‐Fernández, Kelsi R. Hall, Anton A. Stepnov, Morten Sørlie, Åsmund Kjendseth Røhr, and Vincent G. H. Eijsink

Subjects

Structural Biology, Genetics, Biophysics, Cell Biology, Molecular Biology, Biochemistry

Published

2023

2. The interplay between lytic polysaccharide monooxygenases and glycoside hydrolases

Author

Morten Sørlie, Malene Billeskov Keller, and Peter Westh

Subjects

Molecular Biology, Biochemistry

Abstract

In nature, enzymatic degradation of recalcitrant polysaccharides such as chitin and cellulose takes place by a synergistic interaction between glycoside hydrolases (GHs) and lytic polysaccharide monooxygenases (LPMOs). The two different families of carbohydrate-active enzymes use two different mechanisms when breaking glycosidic bonds between sugar moieties. GHs employ a hydrolytic activity and LPMOs are oxidative. Consequently, the topologies of the active sites differ dramatically. GHs have tunnels or clefts lined with a sheet of aromatic amino acid residues accommodating single polymer chains being threaded into the active site. LPMOs are adapted to bind to the flat crystalline surfaces of chitin and cellulose. It is believed that the LPMO oxidative mechanism provides new chain ends that the GHs can attach to and degrade, often in a processive manner. Indeed, there are many reports of synergies as well as rate enhancements when LPMOs are applied in concert with GHs. Still, these enhancements vary in magnitude with respect to the nature of the GH and the LPMO. Moreover, impediment of GH catalysis is also observed. In the present review, we discuss central works where the interplay between LPMOs and GHs has been studied and comment on future challenges to be addressed to fully use the potential of this interplay to improve enzymatic polysaccharide degradation.

Published

2023

3. Engineering cellulases for conversion of lignocellulosic biomass

Author

Yogesh B Chaudhari, Anikó Várnai, Morten Sørlie, Svein J Horn, and Vincent G H Eijsink

Subjects

Bioengineering, Molecular Biology, Biochemistry, Biotechnology

Abstract

Lignocellulosic biomass is a renewable source of energy, chemicals and materials. Many applications of this resource require the depolymerization of one or more of its polymeric constituents. Efficient enzymatic depolymerization of cellulose to glucose by cellulases and accessory enzymes such as lytic polysaccharide monooxygenases is a prerequisite for economically viable exploitation of this biomass. Microbes produce a remarkably diverse range of cellulases, which consist of glycoside hydrolase (GH) catalytic domains and, although not in all cases, substrate-binding carbohydrate-binding modules (CBMs). As enzymes are a considerable cost factor, there is great interest in finding or engineering improved and robust cellulases, with higher activity and stability, easy expression, and minimal product inhibition. This review addresses relevant engineering targets for cellulases, discusses a few notable cellulase engineering studies of the past decades and provides an overview of recent work in the field.

Published

2023

4. Fast and Specific Peroxygenase Reactions Catalyzed by Fungal Mono-Copper Enzymes

Author

Anton A. Stepnov, Morten Sørlie, Lukas Rieder, and Vincent G. H. Eijsink

Subjects

Biomass, chemistry.chemical_element, Lentinula, Polysaccharide, Biochemistry, Article, Mixed Function Oxygenases, Catalysis, Fungal Proteins, Polysaccharides, Catalytic Domain, Enzyme Assays, chemistry.chemical_classification, Neurospora crassa, Hydrogen Peroxide, Monooxygenase, Copper, Recombinant Proteins, Kinetics, Biodegradation, Environmental, Enzyme, chemistry, Lytic cycle, Degradation (geology)

Abstract

The copper-dependent lytic polysaccharide monooxygenases (LPMOs) are receiving attention because of their role in the degradation of recalcitrant biomass and their intriguing catalytic properties. The fundamentals of LPMO catalysis remain somewhat enigmatic as the LPMO reaction is affected by a multitude of LPMO- and co-substrate-mediated (side) reactions that result in a complex reaction network. We have performed kinetic studies with two LPMOs that are active on soluble substrates, NcAA9C and LsAA9A, using various reductants typically employed for LPMO activation. Studies with NcAA9C under “monooxygenase” conditions showed that the impact of the reductant on catalytic activity is correlated with the hydrogen peroxide-generating ability of the LPMO-reductant combination, supporting the idea that a peroxygenase reaction is taking place. Indeed, the apparent monooxygenase reaction could be inhibited by a competing H2O2-consuming enzyme. Interestingly, these fungal AA9-type LPMOs were found to have higher oxidase activity than bacterial AA10-type LPMOs. Kinetic analysis of the peroxygenase activity of NcAA9C on cellopentaose revealed a fast stoichiometric conversion of high amounts of H2O2 to oxidized carbohydrate products. A kcat value of 124 ± 27 s–1 at 4 °C is 20 times higher than a previously described kcat for peroxygenase activity on an insoluble substrate (at 25 °C) and some 4 orders of magnitude higher than typical “monooxygenase” rates. Similar studies with LsAA9A revealed differences between the two enzymes but confirmed fast and specific peroxygenase activity. These results show that the catalytic site arrangement of LPMOs provides a unique scaffold for highly efficient copper redox catalysis.

Published

2021

5. Novel molecular biological tools for the efficient expression of fungal lytic polysaccharide monooxygenases in Pichia pastoris

Author

Lukas Rieder, Katharina Ebner, Anton Glieder, and Morten Sørlie

Subjects

Signal peptide, Management, Monitoring, Policy and Law, Polysaccharide, Applied Microbiology and Biotechnology, Pichia pastoris, 03 medical and health sciences, Signal peptide cleaving, Simplified expression, TP315-360, Glycosyltransferase, LPMO, 030304 developmental biology, chemistry.chemical_classification, Cloning, 0303 health sciences, biology, 030306 microbiology, Renewable Energy, Sustainability and the Environment, Research, Monooxygenase, biology.organism_classification, Fuel, General Energy, Enzyme, Biochemistry, chemistry, Lytic cycle, biology.protein, TP248.13-248.65, Biotechnology

Abstract

Background Lytic polysaccharide monooxygenases (LPMOs) are attracting large attention due their ability to degrade recalcitrant polysaccharides in biomass conversion and to perform powerful redox chemistry. Results We have established a universal Pichia pastoris platform for the expression of fungal LPMOs using state-of-the-art recombination cloning and modern molecular biological tools to achieve high yields from shake-flask cultivation and simple tag-less single-step purification. Yields are very favorable with up to 42 mg per liter medium for four different LPMOs spanning three different families. Moreover, we report for the first time of a yeast-originating signal peptide from the dolichyl-diphosphooligosaccharide-protein glycosyltransferase subunit 1 (OST1) form S. cerevisiae efficiently secreting and successfully processes the N-terminus of LPMOs yielding in fully functional enzymes. Conclusion The work demonstrates that the industrially most relevant expression host P. pastoris can be used to express fungal LPMOs from different families in high yields and inherent purity. The presented protocols are standardized and require little equipment with an additional advantage with short cultivation periods.

Published

2021

6. Chemoenzymatic Synthesis of Chito-oligosaccharides with Alternating N-<scp>d</scp>-Acetylglucosamine and <scp>d</scp>-Glucosamine

Author

Stephen G. Withers, Vincent G. H. Eijsink, Rianne A G Harmsen, Jogi Madhuprakash, Morten Sørlie, Ethan D. Goddard-Borger, Berit Bjugan Aam, and Anne Grethe Hamre

Subjects

chemistry.chemical_classification, 0303 health sciences, biology, Stereochemistry, Aspergillus niger, 010402 general chemistry, biology.organism_classification, 01 natural sciences, Biochemistry, Serratia proteamaculans, Chemical synthesis, 0104 chemical sciences, Acetylglucosamine, 03 medical and health sciences, chemistry.chemical_compound, Enzyme, chemistry, Glucosamine, Serratia marcescens, Glycoside hydrolase, 030304 developmental biology

Abstract

Chito-oligosaccharides (CHOS) are homo- or hetero-oligomers of N-acetylglucosamine (GlcNAc, A) and d-glucosamine (GlcN, D). Production of well-defined CHOS-mixtures, or even pure CHOS, with specific lengths and sugar compositions, is of great interest since these oligosaccharides have interesting bioactivities. While direct chemical synthesis of CHOS is not straightforward, chemo-enzymatic approaches have shown some promise. We have used engineered glycoside hydrolases to catalyze oligomerization of activated DA building blocks through transglycosylation reactions. The building blocks were generated from readily available (GlcNAc)2-para-nitrophenol through deacetylation of the nonreducing end sugar with a recombinantly expressed deacetylase from Aspergillus niger (AnCDA9). This approach, using a previously described hyper-transglycosylating variant of ChiA from Serratia marcescens (SmChiA) and a newly generated transglycosylating variant of Chitinase D from Serratia proteamaculans (SpChiD), led to production of CHOS containing up to ten alternating D and A units [(DA)2, (DA)3, (DA)4, and (DA)5]. The most abundant compounds were purified and characterized. Finally, we demonstrate that (DA)3 generated in this study may serve as a specific inhibitor of the human chitotriosidase. Inhibition of this enzyme has been suggested as a therapeutic strategy against systemic sclerosis.

Published

2020

7. Mechanistic basis of substrate–O2coupling within a chitin-active lytic polysaccharide monooxygenase: An integrated NMR/EPR study

Author

Alessandro Paradisi, Finn Lillelund Aachmann, Gaston Courtade, Zarah Forsberg, Gideon J. Davies, Peter J. Lindley, Reinhard Wimmer, Luisa Ciano, Paul H. Walton, Vincent G. H. Eijsink, and Morten Sørlie

Subjects

Coordination sphere, Chitin, chitin, 010402 general chemistry, Biochemistry, 01 natural sciences, Mixed Function Oxygenases, Substrate Specificity, law.invention, 03 medical and health sciences, Protein structure, Bacterial Proteins, law, Catalytic Domain, Bacillus licheniformis, Molecular orbital, Spectroscopy, Electron paramagnetic resonance, 030304 developmental biology, 0303 health sciences, Multidisciplinary, biology, Chemistry, Electron Spin Resonance Spectroscopy, Active site, Substrate (chemistry), Nuclear magnetic resonance spectroscopy, Biological Sciences, Magnetic Resonance Imaging, NMR, 0104 chemical sciences, 3. Good health, Oxygen, Crystallography, copper, biology.protein, lytic polysaccharide monooxygenase, EPR

Abstract

Significance Lytic polysaccharide monooxygenases (LPMOs) have unique catalytic centers, at which a single copper catalyzes the oxidative cleavage of a glycosidic bond. The mechanism by which LPMOs activate molecular oxygen is key to understanding copper (bio)catalysis but remains poorly understood, largely because the insoluble and heterogeneous nature of LPMO substrates precludes the use of usual laboratory techniques. Using an integrated NMR/EPR approach, we have unraveled structural and electronic details of the interactions of an LPMO from Bacillus licheniformis and β-chitin. EPR spectroscopy on uniformly isotope 15N-labeled 63Cu(II)-LPMO provided insight into substrate-driven rearrangement of the copper coordination sphere that predisposes the enzyme for O2 activation., Lytic polysaccharide monooxygenases (LPMOs) have a unique ability to activate molecular oxygen for subsequent oxidative cleavage of glycosidic bonds. To provide insight into the mode of action of these industrially important enzymes, we have performed an integrated NMR/electron paramagnetic resonance (EPR) study into the detailed aspects of an AA10 LPMO–substrate interaction. Using NMR spectroscopy, we have elucidated the solution-phase structure of apo-BlLPMO10A from Bacillus licheniformis, along with solution-phase structural characterization of the Cu(I)-LPMO, showing that the presence of the metal has minimal effects on the overall protein structure. We have, moreover, used paramagnetic relaxation enhancement (PRE) to characterize Cu(II)-LPMO by NMR spectroscopy. In addition, a multifrequency continuous-wave (CW)-EPR and 15N-HYSCORE spectroscopy study on the uniformly isotope-labeled 63Cu(II)-bound 15N-BlLPMO10A along with its natural abundance isotopologue determined copper spin-Hamiltonian parameters for LPMOs to markedly improved accuracy. The data demonstrate that large changes in the Cu(II) spin-Hamiltonian parameters are induced upon binding of the substrate. These changes arise from a rearrangement of the copper coordination sphere from a five-coordinate distorted square pyramid to one which is four-coordinate near-square planar. There is also a small reduction in metal–ligand covalency and an attendant increase in the d(x2−y2) character/energy of the singly occupied molecular orbital (SOMO), which we propose from density functional theory (DFT) calculations predisposes the copper active site for the formation of a stable Cu–O2 intermediate. This switch in orbital character upon addition of chitin provides a basis for understanding the coupling of substrate binding with O2 activation in chitin-active AA10 LPMOs.

Published

2020

8. Kinetic Characterization of a Putatively Chitin-Active LPMO Reveals a Preference for Soluble Substrates and Absence of Monooxygenase Activity

Author

Vincent G. H. Eijsink, Priit Väljamäe, Dejan M. Petrović, Lukas Rieder, and Morten Sørlie

Subjects

chemistry.chemical_classification, Oxidase test, peroxygenase activity, fungi, Glycosidic bond, General Chemistry, Monooxygenase, H2O2 tolerance, Polysaccharide, Catalysis, redox potential, Cell wall, chemistry.chemical_compound, Enzyme, chemistry, Chitin, Biochemistry, kinetics, LPMO, Cellulose, oxidase activity, Research Article

Abstract

Enzymes known as lytic polysaccharide monooxygenases (LPMOs) are recognized as important contributors to aerobic enzymatic degradation of recalcitrant polysaccharides such as chitin and cellulose. LPMOs are remarkably abundant in nature, with some fungal species possessing more than 50 LPMO genes, and the biological implications of this diversity remain enigmatic. For example, chitin-active LPMOs have been encountered in biological niches where chitin conversion does not seem to take place. We have carried out an in-depth kinetic characterization of a putatively chitin-active LPMO from Aspergillus fumigatus (AfAA11B), which, as we show here, has multiple unusual properties, such as a low redox potential and high oxidase activity. Furthermore, AfAA11B is hardly active on chitin, while being very active on soluble oligomers of N-acetylglucosamine. In the presence of chitotetraose, the enzyme can withstand considerable amounts of H2O2, which it uses to efficiently and stoichiometrically convert this substrate. The unique properties of AfAA11B allowed experiments showing that it is a strict peroxygenase and does not catalyze a monooxygenase reaction. This study shows that nature uses LPMOs for breaking glycosidic bonds in non-polymeric substrates in reactions that depend on H2O2. The quest for the true substrates of these enzymes, possibly carbohydrates in the cell wall of the fungus or its competitors, will be of major interest.

Published

2021

9. Lytic Polysaccharide Monooxygenases in Enzymatic Processing of Lignocellulosic Biomass

Author

Åsmund K. Røhr, Svein Jarle Horn, Anikó Várnai, Morten Sørlie, Bastien Bissaro, Vincent G. H. Eijsink, and Piotr Chylenski

Subjects

chemistry.chemical_classification, 010405 organic chemistry, education, Lignocellulosic biomass, Biomass, General Chemistry, Monooxygenase, 010402 general chemistry, Polysaccharide, 01 natural sciences, humanities, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, Enzyme, chemistry, Biochemistry, Lytic cycle, Cellulose, Hydrogen peroxide, health care economics and organizations

Abstract

The discovery of lytic polysaccharide monooxygenases (LPMOs) has revolutionized enzymatic processing of polysaccharides, in particular, recalcitrant insoluble polysaccharides, such as cellulose. Th...

Published

2019

10. Thermodynamic Signatures of Substrate Binding for Three Thermobifida fusca Cellulases with Different Modes of Action

Author

Anne Grethe Hamre, Priit Väljamäe, Christina M. Payne, Anita Kaupang, and Morten Sørlie

Subjects

Anomer, Stereochemistry, Oligosaccharides, Cellulase, Oxygen Isotopes, Ligands, Biochemistry, chemistry.chemical_compound, Hydrolysis, Bacterial Proteins, Catalytic Domain, Glycoside hydrolase, Cellulose, Glucans, biology, Substrate (chemistry), Isothermal titration calorimetry, Thermobifida, Actinobacteria, chemistry, Mutation, Mutagenesis, Site-Directed, biology.protein, Thermodynamics, Protein Binding, Entropy (order and disorder)

Abstract

The enzymatic breakdown of recalcitrant polysaccharides is achieved by synergistic enzyme cocktails of glycoside hydrolases (GHs) and accessory enzymes. Many GHs are processive, meaning that they stay bound to the substrate between subsequent catalytic interactions. Cellulases are GHs that catalyze the hydrolysis of cellulose [β-1,4-linked glucose (Glc)]. Here, we have determined the relative subsite binding affinity for a glucose moiety as well as the thermodynamic signatures for (Glc)6 binding to three of the seven cellulases produced by the bacterium Thermobifida fusca. TfCel48A is exo-processive, TfCel9A endo-processive, and TfCel5A endo-nonprocessive. Initial hydrolysis of (Glc)5 and (Glc)6 was performed in H218O enabling the incorporation of an 18O atom at the new reducing end anomeric carbon. A matrix-assisted laser desorption ionization time-of-flight mass spectrometry analysis of the products reveals the intensity ratios of otherwise identical 18O- and 16O-containing products to provide insight into how the substrate is placed during productive binding. The two processive cellulases have significant binding affinity in subsites where products dissociate during processive hydrolysis, aligned with a need to have a pushing potential to remove obstacles on the substrate. Moreover, we observed a correlation between processive ability and favorable binding free energy, as previously postulated. Upon ligand binding, the largest contribution to the binding free energy is desolvation for all three cellulases as determined by isothermal titration calorimetry. The two endo-active cellulases show a more favorable solvation entropy change compared to the exo-active cellulase, while the two processive cellulases have less favorable changes in binding enthalpy compared to the nonprocessive TfCel5A.

Published

2019

11. Kinetic insights into the role of the reductant in H2O2-driven degradation of chitin by a bacterial lytic polysaccharide monooxygenase

Author

Morten Sørlie, Riin Kont, Bastien Bissaro, Vincent G. H. Eijsink, Priit Väljamäe, Silja Kuusk, Piret Kuusk, and Agnes Heering

Subjects

0301 basic medicine, chemistry.chemical_classification, 030102 biochemistry & molecular biology, biology, Electron donor, Cell Biology, Monooxygenase, Ascorbic acid, Polysaccharide, Biochemistry, Combinatorial chemistry, Catalysis, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, chemistry, Chitin, biology.protein, Enzyme kinetics, Molecular Biology, Peroxidase

Abstract

Lytic polysaccharide monooxygenases (LPMOs) are monocopper enzymes that catalyze oxidative cleavage of glycosidic bonds in polysaccharides in the presence of an external electron donor (reductant). In the classical O2-driven monooxygenase reaction, the reductant is needed in stoichiometric amounts. In a recently discovered, more efficient H2O2-driven reaction, the reductant would be needed only for the initial reduction (priming) of the LPMO to its catalytically active Cu(I) form. However, the influence of the reductant on reducing the LPMO or on H2O2 production in the reaction remains undefined. Here, we conducted a detailed kinetic characterization to investigate how the reductant affects H2O2-driven degradation of 14C-labeled chitin by a bacterial LPMO, SmLPMO10A (formerly CBP21). Sensitive detection of 14C-labeled products and careful experimental set-ups enabled discrimination between the effects of the reductant on LPMO priming and other effects, in particular enzyme-independent production of H2O2 through reactions with O2 When supplied with H2O2, SmLPMO10A catalyzed 18 oxidative cleavages per molecule of ascorbic acid, suggesting a "priming reduction" reaction. The dependence of initial rates of chitin degradation on reductant concentration followed hyperbolic saturation kinetics, and differences between the reductants were manifested in large variations in their half-saturating concentrations (K mR app). Theoretical analyses revealed that K mR app decreases with a decreasing rate of polysaccharide-independent LPMO reoxidation (by either O2 or H2O2). We conclude that the efficiency of LPMO priming depends on the relative contributions of reductant reactivity, on the LPMO's polysaccharide monooxygenase/peroxygenase and reductant oxidase/peroxidase activities, and on reaction conditions, such as O2, H2O2, and polysaccharide concentrations.

Published

2019

12. Treatment of recalcitrant crystalline polysaccharides with lytic polysaccharide monooxygenase relieves the need for glycoside hydrolase processivity

Author

Daniel Gustavsen, Morten Sørlie, Vincent G. H. Eijsink, Gustav Vaaje-Kolstad, Anne-Grethe Skaarberg Strømnes, and Anne Grethe Hamre

Subjects

Models, Molecular, Protein Conformation, Chitin, 010402 general chemistry, Polysaccharide, 01 natural sciences, Biochemistry, Analytical Chemistry, chemistry.chemical_compound, Polysaccharides, Glycoside hydrolase, Cellulose, Serratia marcescens, chemistry.chemical_classification, biology, 010405 organic chemistry, Hydrolysis, Chitinases, Organic Chemistry, Glycosidic bond, General Medicine, Processivity, 0104 chemical sciences, Kinetics, Enzyme, chemistry, Chitinase, biology.protein

Abstract

Processive glycoside hydrolases associate with recalcitrant polysaccharides such as cellulose and chitin and repeatedly cleave glycosidic linkages without fully dissociating from the crystalline surface. The processive mechanism is efficient in the degradation of insoluble substrates, but comes at the cost of reduced enzyme speed. We show that less processive chitinase variants with reduced ability to degrade crystalline chitin, regain much of this ability when combined with a lytic polysaccharide monooxygenase (LPMO). When combined with an LPMO, several less processive chitinase mutants showed equal or even increased activity on chitin compared to the wild-type. Thus, LPMOs affect the need for processivity in polysaccharide degrading enzyme cocktails, which implies that the composition of such cocktails may need reconsideration.

Published

2019

13. Genomic and Proteomic Study of Andreprevotia ripae Isolated from an Anthill Reveals an Extensive Repertoire of Chitinolytic Enzymes

Author

Gustav Vaaje-Kolstad, Morten Sørlie, Thomas Hahn, Vincent G. H. Eijsink, Silje Benedicte Lorentzen, Magnus Ø. Arntzen, Susanne Zibek, Tina R. Tuveng, and Publica

Subjects

0301 basic medicine, chemistry.chemical_classification, 030102 biochemistry & molecular biology, biology, Chemistry, macromolecular substances, General Chemistry, biology.organism_classification, Polysaccharide, Proteomics, Biochemistry, Genome, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Enzyme, Chitin, Chitinase, biology.protein, Carbohydrate-binding module, Bacteria

Abstract

Chitin is an abundant natural polysaccharide that is hard to degrade because of its crystalline nature and because it is embedded in robust co-polymeric materials containing other polysaccharides, proteins, and minerals. Thus, it is of interest to study the enzymatic machineries of specialized microbes found in chitin-rich environments. We describe a genomic and proteomic analysis of Andreprevotia ripae, a chitinolytic Gram-negative bacterium isolated from an anthill. The genome of A. ripae encodes four secreted family GH19 chitinases of which two were detected and upregulated during growth on chitin. In addition, the genome encodes as many as 25 secreted GH18 chitinases, of which 17 were detected and 12 were upregulated during growth on chitin. Finally, the single lytic polysaccharide monooxygenase (LPMO) was strongly upregulated during growth on chitin. Whereas 66% of the 29 secreted chitinases contained two carbohydrate-binding modules (CBMs), this fraction was 93% (13 out of 14) for the upregulated chitinases, suggesting an important role for these CBMs. Next to an unprecedented multiplicity of upregulated chitinases, this study reveals several chitin-induced proteins that contain chitin-binding CBMs but lack a known catalytic function. These proteins are interesting targets for discovery of enzymes used by nature to convert chitin-rich biomass. The MS proteomic data have been deposited in the PRIDE database with accession number PXD025087.

Published

2021

14. Methylation of the N-terminal histidine protects a lytic polysaccharide monooxygenase from auto-oxidative inactivation

Author

Morten Sørlie, Dejan M. Petrović, Piotr Chylenski, Vincent G. H. Eijsink, Anikó Várnai, Bastien Bissaro, Finn Lillelund Aachmann, Gaston Courtade, Morten Skaugen, and Marianne Slang Jensen

Subjects

0106 biological sciences, 0301 basic medicine, chemistry.chemical_classification, Reactive oxygen species, Oxidative phosphorylation, Methylation, Monooxygenase, 01 natural sciences, Biochemistry, Xyloglucan, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Enzyme, chemistry, Lytic cycle, 010608 biotechnology, Molecular Biology, Histidine

Abstract

The catalytically crucial N-terminal histidine (His1) of fungal lytic polysaccharide monooxygenases (LPMOs) is post-translationally modified to carry a methylation. The functional role of this methylation remains unknown. We have carried out an in-depth functional comparison of two variants of a family AA9 LPMO from Thermoascus aurantiacus (TaLPMO9A), one with, and one without the methylation on His1. Various activity assays showed that the two enzyme variants are identical in terms of substrate preferences, cleavage specificities and the ability to activate molecular oxygen. During the course of this work, new functional features of TaLPMO9A were discovered, in particular the ability to cleave xyloglucan, and these features were identical for both variants. Using a variety of techniques, we further found that methylation has minimal effects on the pKa of His1, the affinity for copper and the redox potential of bound copper. The two LPMOs did, however, show clear differences in their resistance against oxidative damage. Studies with added hydrogen peroxide confirmed recent claims that low concentrations of H2 O2 boost LPMO activity, whereas excess H2 O2 leads to LPMO inactivation. The methylated variant of TaLPMO9A, produced in Aspergillus oryzae, was more resistant to excess H2 O2 and showed better process performance when using conditions that promote generation of reactive-oxygen species. LPMOs need to protect themselves from reactive oxygen species generated in their active sites and this study shows that methylation of the fully conserved N-terminal histidine provides such protection.

Published

2018

15. Key Residues Affecting Transglycosylation Activity in Family 18 Chitinases: Insights into Donor and Acceptor Subsites

Author

Morten Sørlie, T. Swaroopa Rani, Bjørn Dalhus, Vincent G. H. Eijsink, Appa Rao Podile, and Jogi Madhuprakash

Subjects

Models, Molecular, 0301 basic medicine, Glycosylation, Serratia, Stereochemistry, Mutant, Chitobiose, Crystallography, X-Ray, Disaccharides, 010402 general chemistry, 01 natural sciences, Biochemistry, Serratia proteamaculans, Serratia Infections, 03 medical and health sciences, chemistry.chemical_compound, Hydrolase, Glycoside hydrolase, Amino Acid Sequence, Asparagine, Serratia marcescens, biology, Hydrolysis, Chitinases, biology.organism_classification, 0104 chemical sciences, 030104 developmental biology, chemistry, Mutation, Chitinase, biology.protein, Sequence Alignment

Abstract

Understanding features that determine transglycosylation (TG) activity in glycoside hydrolases is important because it would allow the construction of enzymes that can catalyze controlled synthesis of oligosaccharides. To increase TG activity in two family 18 chitinases, chitinase D from Serratia proteamaculans ( SpChiD) and chitinase A from Serratia marcescens ( SmChiA), we have mutated residues important for stabilizing the reaction intermediate and substrate binding in both donor and acceptor sites. To help mutant design, the crystal structure of the inactive SpChiD-E153Q mutant in complex with chitobiose was determined. We identified three mutations with a beneficial effect on TG activity: Y28A (affecting the -1 subsite and the intermediate), Y222A (affecting the intermediate), and Y226W (affecting the +2 subsite). Furthermore, exchange of D151, the middle residue in the catalytically important DXDXE motif, to asparagine reduced hydrolytic activity ≤99% with a concomitant increase in apparent TG activity. The combination of mutations yielded even higher degrees of TG activity. Reactions with the best mutant, SpChiD-D151N/Y226W/Y222A, led to rapid accumulation of high levels of TG products that remained stable over time. Importantly, the introduction of analogous mutations at the same positions in SmChiA (Y163A equal to Y28A and Y390F similar to Y222A) had similar effects on TG efficiency. Thus, the combination of the decreasing hydrolytic power, subsite affinity, and stability of intermediate states provides a powerful, general strategy for creating hypertransglycosylating mutants of retaining glycoside hydrolases.

Published

2018

16. NMR and fluorescence spectroscopies reveal the preorganized binding site in family 14 carbohydrate-binding module from human chitotriosidase

Author

Finn Lillelund Aachmann, Morten Sørlie, Oscar Crasson, Eva Madland, and Marylène Vandevenne

Subjects

Chemistry, Biochemistry, General Chemical Engineering, General Chemistry, Carbohydrate-binding module, Binding site, Fluorescence, Solution structure, Carbohydrate active enzymes, QD1-999, Article

Abstract

Carbohydrate-binding modules (CBM) play important roles in targeting and increasing the concentration of carbohydrate active enzymes on their substrates. Using NMR to get the solution structure of CBM14, we can gain insight into secondary structure elements and intramolecular interactions with our assigned nuclear overhauser effect peaks. This reveals that two conserved aromatic residues (Phe437 and Phe456) make up the hydrophobic core of the CBM. These residues are also responsible for connecting the two β-sheets together, by being part of β2 and β4, respectively, and together with disulfide bridges, they create CBM14’s characteristic “hevein-like” fold. Most CBMs rely on aromatic residues for substrate binding; however, CBM14 contains just a single tryptophan (Trp465) that together with Asn466 enables substrate binding. Interestingly, an alanine mutation of a single residue (Leu454) located behind Trp465 renders the CBM incapable of binding. Fluorescence spectroscopy performed on this mutant reveals a significant blue shift, as well as a minor blue shift for its neighbor Val455. The reduction in steric hindrance causes the tryptophan to be buried into the hydrophobic core of the structure and therefore suggests a preorganized binding site for this CBM. Our results show that both Trp465 and Asn466 are affected when CBM14 interacts with both (GlcNAc)3 and β-chitin, that the binding interactions are weak, and that CBM14 displays a slightly higher affinity toward β-chitin. This is an open access article published under an ACS AuthorChoice License, which permits copying and redistribution of the article or any adaptations for non-commercial purposes.

Published

2019

17. Polysaccharide degradation by lytic polysaccharide monooxygenases

Author

Gustav Vaaje-Kolstad, Åsmund K. Røhr, Morten Sørlie, Finn Lillelund Aachmann, Gaston Courtade, Bastien Bissaro, Dejan M. Petrović, Vincent G. H. Eijsink, Zarah Forsberg, Biodiversité et Biotechnologie Fongiques (BBF), and Aix Marseille Université (AMU)-École Centrale de Marseille (ECM)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)

Subjects

[SDV]Life Sciences [q-bio], Sequence (biology), Polysaccharide, Catalysis, Mixed Function Oxygenases, Substrate Specificity, Structure-Activity Relationship, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Chitin, Polysaccharides, Structural Biology, Catalytic Domain, Cellulose, Molecular Biology, Phylogeny, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Hydrolysis, Glycosidic bond, Hydrogen Peroxide, Monooxygenase, Oxygen, Enzyme, chemistry, Lytic cycle, Biochemistry, Oxidation-Reduction, 030217 neurology & neurosurgery, Protein Binding

Abstract

The discovery of oxidative cleavage of glycosidic bonds by enzymes currently known as lytic polysaccharide monooxygenases (LPMOs) has had a major impact on our current understanding of the enzymatic conversion of recalcitrant polysaccharides such as chitin and cellulose. The number of LPMO sequence families keeps expanding and novel substrate specificities and biological functionalities are being discovered. The catalytic mechanism of these LPMOs remains somewhat enigmatic. Recently, novel insights have been obtained from studies of enzyme–substrate complexes by X-ray crystallography, EPR, NMR, and modeling. Furthermore, it has been shown that LPMOs may carry out peroxygenase reactions, at much higher rates than monooxygenase reactions, which affects our understanding and exploitation of these powerful enzymes. © 2019 The Authors. Published by Elsevier Ltd. This article is available under the Creative Commons CC-BY-NC-ND license and permits non-commercial use of the work as published, without adaptation or alteration provided the work is fully attributed.

Published

2019

18. Antifungal activity of well-defined chitooligosaccharide preparations against medically relevant yeasts

Author

Peter Gaustad, Morten Sørlie, Silje Benedicte Lorentzen, Oddmund Bakke, Berit Bjugan Aam, Svein Halvor Knutsen, Jane Wittrup Agger, Vincent G. H. Eijsink, M. Ganan, and Catherine Anne Heyward

Subjects

0301 basic medicine, Antifungal Agents, Cell Membranes, Drug Evaluation, Preclinical, Oligosaccharides, Yeast and Fungal Models, Degree of polymerization, Pathology and Laboratory Medicine, Polymerization, Chitosan, chemistry.chemical_compound, Yeasts, Medicine and Health Sciences, Candida albicans, Candida, Fungicides, chemistry.chemical_classification, Fungal Pathogens, Multidisciplinary, biology, Molecular Structure, Antimicrobials, Fungal Diseases, Chemical Reactions, Drugs, Eukaryota, Agriculture, Oligosaccharide, Chemistry, Infectious Diseases, Biochemistry, Experimental Organism Systems, Medical Microbiology, Physical Sciences, Cell disruption, Medicine, Pathogens, Cellular Structures and Organelles, Agrochemicals, Research Article, Imaging Techniques, Science, 030106 microbiology, Mycology, Microbial Sensitivity Tests, Research and Analysis Methods, Microbiology, 03 medical and health sciences, Structure-Activity Relationship, Microbial Control, Fluorescence Imaging, Candida Albicans, Humans, Microbial Pathogens, Pharmacology, Antifungals, Organisms, Fungi, Biology and Life Sciences, Cell Biology, biology.organism_classification, Polymer Chemistry, Yeast, Molecular Weight, 030104 developmental biology, Yeast Infections, chemistry, Mycoses, Solubility, Acetylation, Animal Studies

Abstract

Due to their antifungal activity, chitosan and its derivatives have potential to be used for treating yeast infections in humans. However, to be considered for use in human medicine, it is necessary to control and know the chemical composition of the compound, which is not always the case for polymeric chitosans. Here, we analyze the antifungal activity of a soluble and well-defined chito-oligosaccharide (CHOS) with an average polymerization degree (DPn) of 32 and fraction of acetylation (FA) of 0.15 (C32) on 52 medically relevant yeast strains. Minimal inhibitory concentrations (MIC) varied widely among yeast species, strains and isolates (from > 5000 to < 9.77 μg mL-1) and inhibition patterns showed a time- and dose-dependencies. The antifungal activity was predominantly fungicidal and was inversely proportional to the pH, being maximal at pH 4.5, the lowest tested pH. Furthermore, antifungal effects of CHOS fractions with varying average molecular weight indicated that those fractions with an intermediate degree of polymerization, i.e. DP 31 and 54, had the strongest inhibitory effects. Confocal imaging showed that C32 adsorbs to the cell surface, with subsequent cell disruption and accumulation of C32 in the cytoplasm. Thus, C32 has potential to be used as a therapy for fungal infections.

Published

2019

19. Aromatic-Mediated Carbohydrate Recognition in Processive Serratia marcescens Chitinases

Author

Christina M. Payne, Anne Grethe Hamre, Patricia Wildberger, Morten Sørlie, Vincent G. H. Eijsink, Suvamay Jana, Matilde Mengkrog Holen, and Gregg T. Beckham

Subjects

0301 basic medicine, Chitin, Molecular Dynamics Simulation, 010402 general chemistry, Polysaccharide, 01 natural sciences, 03 medical and health sciences, Hydrolysis, chemistry.chemical_compound, Bacterial Proteins, Catalytic Domain, Materials Chemistry, Glycoside hydrolase, Physical and Theoretical Chemistry, Serratia marcescens, chemistry.chemical_classification, biology, Chemistry, Chitinases, Substrate (chemistry), Glycosidic bond, biology.organism_classification, 0104 chemical sciences, Surfaces, Coatings and Films, 030104 developmental biology, Enzyme, Biochemistry, Mutagenesis, Site-Directed, Thermodynamics

Abstract

Microorganisms use a host of enzymes, including processive glycoside hydrolases, to deconstruct recalcitrant polysaccharides to sugars. Processive glycoside hydrolases closely associate with polymer chains and repeatedly cleave glycosidic linkages without dissociating from the crystalline surface after each hydrolytic step; they are typically the most abundant enzymes in both natural secretomes and industrial cocktails by virtue of their significant hydrolytic potential. The ubiquity of aromatic residues lining the enzyme catalytic tunnels and clefts is a notable feature of processive glycoside hydrolases. We hypothesized that these aromatic residues have uniquely defined roles, such as substrate chain acquisition and binding in the catalytic tunnel, that are defined by their local environment and position relative to the substrate and the catalytic center. Here, we investigated this hypothesis with variants of Serratia marcescens family 18 processive chitinases ChiA and ChiB. We applied molecular simulation and free energy calculations to assess active site dynamics and ligand binding free energies. Isothermal titration calorimetry provided further insight into enthalpic and entropic contributions to ligand binding free energy. Thus, the roles of six aromatic residues, Trp-167, Trp-275, and Phe-396 in ChiA, and Trp-97, Trp-220, and Phe-190 in ChiB, have been examined. We observed that point mutation of the tryptophan residues to alanine results in unfavorable changes in the free energy of binding relative to wild-type. The most drastic effects were observed for residues positioned at the "entrances" of the deep substrate-binding clefts and known to be important for processivity. Interestingly, phenylalanine mutations in ChiA and ChiB had little to no effect on chito-oligomer binding, in accordance with the limited effects of their removal on chitinase functionality.

Published

2016

20. Thermodynamic insights into the role of aromatic residues in chitooligosaccharide binding to the transglycosylating chitinase-D from Serratia proteamaculans

Author

Appa Rao Podile, Morten Sørlie, T. Swaroopa Rani, Vincent G. H. Eijsink, and Jogi Madhuprakash

Subjects

Models, Molecular, Chitosan, Binding Sites, Serratia, biology, Chemistry, Hydrolysis, Chitinases, Biophysics, Oligosaccharides, Chitin, biology.organism_classification, Biochemistry, Serratia proteamaculans, Analytical Chemistry, Catalytic Domain, Chitinase, biology.protein, Thermodynamics, Molecular Biology

Published

2020

21. Using chitosan to understand chitinases and the role of processivity in the degradation of recalcitrant polysaccharides

Author

Gustav Vaaje-Kolstad, Morten Sørlie, Svein Jarle Horn, and Vincent G. H. Eijsink

Subjects

0301 basic medicine, chemistry.chemical_classification, 030102 biochemistry & molecular biology, Polymers and Plastics, biology, Depolymerization, General Chemical Engineering, Substrate (chemistry), General Chemistry, Cellulase, Processivity, Polysaccharide, Biochemistry, Chitosan, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, chemistry, Chitin, Materials Chemistry, biology.protein, Environmental Chemistry, Cellulose

Abstract

Enzymatic depolymerization of abundant polysaccharides such as chitin and cellulose is hampered by the recalcitrant, crystalline nature of these materials. Nature musters a large variety of hydrolytic and oxidative enzymes with varying properties that, together, manage the task of saccharifying chitin and cellulose. Processivity, i.e. the ability to carry out multiple hydrolytic reactions while sliding along the polysaccharide chain, is considered a key property of hydrolytic enzymes acting on the most recalcitrant parts of the substrate. Due to the insoluble nature of the substrate, this phenomenon is difficult to study. For family GH18 chitinases, the combination of a catalytic mechanism depending on acetyl groups in the substrate and the possibility to produce partially deacetylated soluble single chitin chains (chitosan) provides a unique tool for studying processivity. Here, we review how the use of well-defined chitosans has helped unraveling crucial and otherwise difficult to study properties of multiple chitinases, including well studied chitinases from Serratia marcescens and human chitotriosidase (HCHT). These studies have yielded pioneering insights into the structural basis and functional implications of processivity that apply to both chitinases and cellulases. Recent studies of processive chitinases and cellulases confirm the insights originally derived from the work with chitosan and take this further, for example by providing kinetic and thermodynamic data for processive enzyme action.

Published

2020

22. Analytical Tools for Characterizing Cellulose-Active Lytic Polysaccharide Monooxygenases (LPMOs)

Author

Bjørge, Westereng, Jennifer S M, Loose, Gustav, Vaaje-Kolstad, Finn L, Aachmann, Morten, Sørlie, and Vincent G H, Eijsink

Subjects

Kinetics, Magnetic Resonance Spectroscopy, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Lithium, Cellulose, Chromatography, Ion Exchange, Biochemistry, Oxidation-Reduction, Copper, Enzyme Assays, Mixed Function Oxygenases, Substrate Specificity

Abstract

Lytic polysaccharide monooxygenases are copper-dependent enzymes that perform oxidative cleavage of glycosidic bonds in cellulose and various other polysaccharides. LPMOs acting on cellulose use a reactive oxygen species to abstract a hydrogen from the C1 or C4, followed by hydroxylation of the resulting substrate radical. The resulting hydroxylated species is unstable, resulting in glycoside bond scission and formation of an oxidized new chain end. These oxidized chain ends are spontaneously hydrated at neutral pH, leading to formation of an aldonic acid or a gemdiol, respectively. LPMO activity may be characterized using a variety of analytic tools, the most common of which are high-performance anion exchange chromatography system with pulsed amperometric detection (HPAEC-PAD) and MALDI-TOF mass spectrometry (MALDI-MS). NMR may be used to increase the certainty of product identifications, in particular the site of oxidation. Kinetic studies of LPMOs have several pitfalls and to avoid these, it is important to secure copper saturation, avoid the presence of free transition metals in solution, and control the amount of reductant (i.e., electron supply to the LPMO). Further insight into LPMO properties may be obtained by determining the redox potential and by determining the affinity for copper. In some cases, substrate affinity can be assessed using isothermal titration calorimetry. These methods are described in this chapter.

Published

2018

23. The effect of the carbohydrate binding module on substrate degradation by the human chitotriosidase

Author

Kristine Bistrup Eide, Håvard Sletta, Anette I. Dybvik, Vincent G. H. Eijsink, Kjell Morten Vårum, Linn Wilhelmsen Stockinger, Anne Tøndervik, and Morten Sørlie

Subjects

Models, Molecular, Gene isoform, Glycosylation, CAZy, Biophysics, Gene Expression, Chitin, Crystallography, X-Ray, Biochemistry, Protein Structure, Secondary, Substrate Specificity, Analytical Chemistry, chemistry.chemical_compound, Catalytic Domain, TIM barrel, Escherichia coli, Humans, Protein Isoforms, Glycoside hydrolase, Molecular Biology, Glycoside hydrolase family 18, Chitosan, Chemistry, Hydrolysis, Processivity, Recombinant Proteins, Kinetics, HEK293 Cells, Hexosaminidases, Biocatalysis, Thermodynamics, Carbohydrate-binding module, Protein Binding

Abstract

Human chitotriosidase (HCHT) is one of two active glycoside hydrolase family 18 chitinases produced by humans. The enzyme is associated with several diseases and is thought to play a role in the anti-parasite responses of the innate immune system. HCHT occurs in two isoforms, one 50 kDa (HCHT50) and one 39 kDa variant (HCHT39). Common for both isoforms is a catalytic domain with the (β/α)8 TIM barrel fold. HCHT50 has an additional linker-region, followed by a C-terminal carbohydrate-binding module (CBM) classified as CBM family 14 in the CAZy database. To gain further insight into enzyme functionality and especially the effect of the CBM, we expressed both isoforms and compared their catalytic properties on chitin and high molecular weight chitosans. HCHT50 degrades chitin faster than HCHT39 and much more efficiently. Interestingly, both HCHT50 and HCHT39 show biphasic kinetics on chitosan degradation where HCHT50 is faster initially and HCHT39 is faster in the second phase. Moreover, HCHT50 produces distinctly different oligomer distributions than HCHT39. This is likely due to increased transglycosylation activity for HCHT50 due the CBM extending the positive subsites binding surface and therefore promoting transglycosylation. Finally, studies with both chitin and chitosan showed that both isoforms have a similarly low degree of processivity. Combining functional and structural features of the two isoforms, it seems that HCHT combines features of exo-processive and endo-nonprocessive chitinases with the somewhat unusual CBM14 to reach a high degree of efficiency, in line with its alleged physiological task of being a “complete” chitinolytic machinery by itself.

Published

2015

24. Thermodynamic Relationships with Processivity in Serratia marcescens Family 18 Chitinases

Author

Morten Sørlie, Geir Mathiesen, Matilde Mengkrog Holen, Anne Grethe Hamre, Christina M. Payne, Suvamay Jana, and Priit Väljamäe

Subjects

chemistry.chemical_classification, biology, Chemistry, Entropy, Chitinases, Active site, Substrate (chemistry), Isothermal titration calorimetry, Processivity, Molecular Dynamics Simulation, Ligands, biology.organism_classification, Surfaces, Coatings and Films, chemistry.chemical_compound, Enzyme, Biochemistry, Chitin, Catalytic Domain, Serratia marcescens, Materials Chemistry, biology.protein, Glycoside hydrolase, Physical and Theoretical Chemistry, hormones, hormone substitutes, and hormone antagonists

Abstract

The enzymatic degradation of recalcitrant polysaccharides is accomplished by synergistic enzyme cocktails of glycoside hydrolases (GHs) and accessory enzymes. Many GHs are processive which means that they remain attached to the substrate in between subsequent hydrolytic reactions. Chitinases are GHs that catalyze the hydrolysis of chitin (β-1,4-linked N-acetylglucosamine). Previously, a relationship between active site topology and processivity has been suggested while recent computational efforts have suggested a link between the degree of processivity and ligand binding free energy. We have investigated these relationships by employing computational (molecular dynamics (MD)) and experimental (isothermal titration calorimetry (ITC)) approaches to gain insight into the thermodynamics of substrate binding to Serratia marcescens chitinases ChiA, ChiB, and ChiC. We show that increased processive ability indeed corresponds to more favorable binding free energy and that this likely is a general feature of GHs. Moreover, ligand binding in ChiB is entropically driven; in ChiC it is enthalpically driven, and the enthalpic and entropic contributions to ligand binding in ChiA are equal. Furthermore, water is shown to be especially important in ChiA-binding. This work provides new insight into oligosaccharide binding, getting us one step closer to understand how GHs efficiently degrade recalcitrant polysaccharides.

Published

2015

25. The Predominant Molecular State of Bound Enzyme Determines the Strength and Type of Product Inhibition in the Hydrolysis of Recalcitrant Polysaccharides by Processive Enzymes

Author

Morten Sørlie, Priit Väljamäe, and Silja Kuusk

Subjects

Hypocrea, Population, Chitin, Cellulase, Cellobiose, Chitobiose, Disaccharides, Polysaccharide, Biochemistry, chemistry.chemical_compound, Polysaccharides, Catalytic Domain, Cellulose 1,4-beta-Cellobiosidase, Animals, Enzyme kinetics, Cellulose, education, Molecular Biology, Serratia marcescens, chemistry.chemical_classification, education.field_of_study, biology, Hydrolysis, Chitinases, Active site, Cell Biology, Nanostructures, Molecular Weight, Kinetics, chemistry, Product inhibition, Enzymology, biology.protein, Protein Binding

Abstract

Processive enzymes are major components of the efficient enzyme systems that are responsible for the degradation of the recalcitrant polysaccharides cellulose and chitin. Despite intensive research, there is no consensus on which step is rate-limiting for these enzymes. Here, we performed a comparative study of two well characterized enzymes, the cellobiohydrolase Cel7A from Hypocrea jecorina and the chitinase ChiA from Serratia marcescens. Both enzymes were inhibited by their disaccharide product, namely chitobiose for ChiA and cellobiose for Cel7A. The products behaved as noncompetitive inhibitors according to studies using the (14)C-labeled crystalline polymeric substrates (14)C chitin nanowhiskers and (14)C-labeled bacterial microcrystalline cellulose for ChiA and Cel7A, respectively. The resulting observed Ki (obs) values were 0.45 ± 0.08 mm for ChiA and 0.17 ± 0.02 mm for Cel7A. However, in contrast to ChiA, the Ki (obs) of Cel7A was an order of magnitude higher than the true Ki value governed by the thermodynamic stability of the enzyme-inhibitor complex. Theoretical analysis of product inhibition suggested that the inhibition strength and pattern can be accounted for by assuming different rate-limiting steps for ChiA and Cel7A. Measuring the population of enzymes whose active site was occupied by a polymer chain revealed that Cel7A was bound predominantly via its active site. Conversely, the active-site-mediated binding of ChiA was slow, and most ChiA exhibited a free active site, even when the substrate concentration was saturating for the activity. Collectively, our data suggest that complexation with the polymer chain is rate-limiting for ChiA, whereas Cel7A is limited by dissociation.

Published

2015

26. Biotransformation of zearalenone and zearalenols to their major glucuronide metabolites reduces estrogenic activity

Author

Silvio Uhlig, Erik Ropstad, Christopher O. Miles, Caroline Frizzell, Christopher T. Elliott, Steven Verhaegen, Morten Sørlie, Lisa Connolly, and Gunnar Sundstøl Eriksen

Subjects

Agonist, Cell Survival, medicine.drug_class, Chemistry, fungi, Estrogen receptor, General Medicine, Mycotoxins, Toxicology, chemistry.chemical_compound, Glucuronides, Biotransformation, Biochemistry, Genes, Reporter, Estrogen, medicine, Zeranol, Humans, Zearalenone, Estrogens, Non-Steroidal, Mycotoxin, Glucuronide

Abstract

Zearalenone (ZEN) is a mycotoxin produced by Fusarium fungi. Once ingested, ZEN may be absorbed and metabolised to α- and β-zearalenol (α-ZOL, β-ZOL), and to a lesser extent α- and β-zearalanol (α-ZAL, β-ZAL). Further biotransformation to glucuronide conjugates also occurs to facilitate the elimination of these toxins from the body. Unlike ZEN and its metabolites, information regarding the estrogenic activity of these glucuronide conjugates in various tissues is lacking. ZEN-14-O-glucuronide, α-ZOL-14-O-glucuronide, α-ZOL-7-O-glucuronide, β-ZOL-14-O-glucuronide and β-ZOL-16-O-glucuronide, previously obtained as the major products from preparative enzymatic synthesis, were investigated for their potential to cause endocrine disruption through interference with estrogen receptor transcriptional activity. All five glucuronide conjugates showed a very weak agonist response in an estrogen responsive reporter gene assay (RGA), with activity ranging from 0.0001% to 0.01% of that of 17β-estradiol, and also less than that of ZEN, α-ZOL and β-ZOL which have previously shown estrogenic potencies of the order 17β-estradiol>α-ZOL>ZEN>β-ZOL. Confirmatory mass spectrometry revealed that any activity observed was likely a result of minor deconjugation of the glucuronide moiety. This study confirms that formation of ZEN and ZOL glucuronides is a detoxification reaction with regard to estrogenicity, serving as a potential host defence mechanism against ZEN-induced estrogenic activity.

Published

2015

27. Activation of enzymatic chitin degradation by a lytic polysaccharide monooxygenase

Author

Morten Sørlie, Anne Grethe Hamre, Kristine Bistrup Eide, and Hanne H. Wold

Subjects

chemistry.chemical_classification, biology, Hydrolysis, Chitinases, Organic Chemistry, Chitin, General Medicine, Monooxygenase, biology.organism_classification, Polysaccharide, Biochemistry, Mixed Function Oxygenases, Substrate Specificity, Analytical Chemistry, chemistry.chemical_compound, Enzyme, Bacterial Proteins, chemistry, Serratia marcescens, Glycoside hydrolase, Cellulose

Abstract

For decades, the enzymatic conversion of recalcitrant polysaccharides such as cellulose and chitin was thought to solely rely on the synergistic action of hydrolytic enzymes, but recent work has shown that lytic polysaccharide monooxygenases (LPMOs) are important contributors to this process. Here, we have examined the initial rate enhancement an LPMO (CBP21) has on the hydrolytic enzymes (ChiA, ChiB, and ChiC) of the chitinolytic machinery of Serratia marcescens through determinations of apparent k(cat) (k(cat)(app)) values on a β-chitin substrate. k(cat)(app) values were determined to be 1.7±0.1 s(-1) and 1.7±0.1 s(-1) for the exo-active ChiA and ChiB, respectively and 1.2±0.1 s(-1) for the endo-active ChiC. The addition of CBP21 boosted the k(cat)(app) values of ChiA and ChiB giving values of 11.1±1.5 s(-1) and 13.9±1.4 s(-1), while there was no effect on ChiC (0.9±0.1 s(-1)).

Published

2015

28. Crystal structure and thermodynamic dissection of chitin oligosaccharide binding to the LysM module of chitinase-A from Pteris ryukyuensis

Author

Yoshihito Kitaoku, Naoyuki Umemoto, Tamo Fukamizo, Takayuki Ohnuma, Morten Sørlie, Toki Taira, and Tomoyuki Numata

Subjects

0301 basic medicine, Stereochemistry, Protein Conformation, Enthalpy, Biophysics, Oligosaccharides, Chitin, Crystal structure, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Oligosaccharide binding, Molecule, Molecular Biology, Binding Sites, biology, Lysine, Chitinases, Solvation, Pteris, Cell Biology, Pteris ryukyuensis, carbohydrates (lipids), Molecular Docking Simulation, Crystallography, 030104 developmental biology, chemistry, Models, Chemical, Chitinase, biology.protein, Thermodynamics, Protein Binding

Abstract

We determined the crystal structure of a LysM module from Pteris ryukyuensis chitinase-A (PrLysM2) at a resolution of 1.8 A. Structural and binding analysis of PrLysM2 indicated that this module recognizes chitin oligosaccharides in a shallow groove comprised of five sugar-binding subsites on one side of the molecule. The free energy changes (ΔGr°) for binding of (GlcNAc)6, (GlcNAc)5, and (GlcNAc)4 to PrLysM2 were determined to be -5.4, -5,4 and -4.6 kcal mol-1, respectively, by ITC. Thermodynamic dissection of the binding energetics of (GlcNAc)6 revealed that the driving force is the enthalpy change (ΔHr° = -11.7 ± 0.2 kcal/mol) and the solvation entropy change (-TΔSsolv° = -5.9 ± 0.6 kcal/mol). This is the first description of thermodynamic signatures of a chitin oligosaccharide binding to a LysM module.

Published

2017

29. Thermodynamics of tunnel formation upon substrate binding in a processive glycoside hydrolase

Author

Emil Ebbestad Frøberg, Anne Grethe Hamre, Vincent G. H. Eijsink, and Morten Sørlie

Subjects

0301 basic medicine, Models, Molecular, Stereochemistry, Entropy, Biophysics, Mutation, Missense, Thermodynamics, Cellulase, Biochemistry, 03 medical and health sciences, Hydrolysis, Catalytic Domain, Glycoside hydrolase, Binding site, Molecular Biology, Serratia marcescens, chemistry.chemical_classification, 030102 biochemistry & molecular biology, biology, Chitinases, Active site, Glycosidic bond, Conformational entropy, 030104 developmental biology, chemistry, Amino Acid Substitution, Chitinase, biology.protein

Abstract

Glycoside hydrolases (GHs) catalyze the hydrolysis of glycosidic bonds and are key enzymes in carbohydrate metabolism. Efficient degradation of recalcitrant polysaccharides such as chitin and cellulose is accomplished due to synergistic enzyme cocktails consisting of accessory enzymes and mixtures of GHs with different modes of action and active site topologies. The substrate binding sites of chitinases and cellulases often have surface exposed aromatic amino acids and a tunnel or cleft topology. The active site of the exo-processive chitinase B (ChiB) from Serratia marcescens is partially closed, creating a tunnel-like catalytic cleft. To gain insight in the fundamental principles of substrate binding in this enzyme, we have studied the contribution of five key residues involved in substrate binding and tunnel formation to the thermodynamics of substrate binding. Mutation of Trp97, Phe190, Trp220 and Glu221, which are all part of the tunnel walls, resulted in significant less favorable conformational entropy change (ΔS°conf) upon binding (-TΔΔS°conf = ∼5 kcal/mol). This suggest that these residues are important for the structural rigidity and pre-shaping of the tunnel prior to binding. Mutation of Asp316, which, by forming a hydrogen bond to Trp97 is crucial in the active-site tunnel roof, resulted in a more favorable ΔS°conf relative to the wild type (-TΔΔS°conf = -2.2 kcal/mol). This shows that closing the tunnel-roof comes with an entropy cost, as previously suggested based on the crystal structures of GHs with tunnel topologies in complex with their substrates.

Published

2017

30. Human Chitotriosidase: Catalytic Domain or Carbohydrate Binding Module, Who’s Leading HCHT’s Biological Function

Author

Marylène Vandevenne, Moreno Galleni, Finn Lillelund Aachmann, Gaston Courtade, Morten Sørlie, Oscar Crasson, Raffaella Parente, François Legrand, Denis Baurain, and Raphaël R. Léonard

Subjects

0301 basic medicine, Models, Molecular, Science, Carbohydrates, Molecular Conformation, Plasma protein binding, Catalysis, Article, Substrate Specificity, 03 medical and health sciences, chemistry.chemical_compound, Structure-Activity Relationship, Chitin, Chitin binding, Catalytic Domain, Humans, Glycoside hydrolase, Binding site, chemistry.chemical_classification, Multidisciplinary, Binding Sites, biology, Glycosidic bond, 030104 developmental biology, Hexosaminidases, chemistry, Biochemistry, Chitinase, biology.protein, Medicine, Carbohydrate-binding module, Protein Binding

Abstract

Chitin is an important structural component of numerous fungal pathogens and parasitic nematodes. The human macrophage chitotriosidase (HCHT) is a chitinase that hydrolyses glycosidic bonds between the N-acetyl-D-glucosamine units of this biopolymer. HCHT belongs to the Glycoside Hydrolase (GH) superfamily and contains a well-characterized catalytic domain appended to a chitin-binding domain (ChBDCHIT1). Although its precise biological function remains unclear, HCHT has been described to be involved in innate immunity. In this study, the molecular basis for interaction with insoluble chitin as well as with soluble chito-oligosaccharides has been determined. The results suggest a new mechanism as a common binding mode for many Carbohydrate Binding Modules (CBMs). Furthermore, using a phylogenetic approach, we have analysed the modularity of HCHT and investigated the evolutionary paths of its catalytic and chitin binding domains. The phylogenetic analyses indicate that the ChBDCHIT1 domain dictates the biological function of HCHT and not its appended catalytic domain. This observation may also be a general feature of GHs. Altogether, our data have led us to postulate and discuss that HCHT acts as an immune catalyser. © 2017 The Authors. Published by Nature Publishing Group. This is an open access article licensed under a Creative Commons Attribution 4.0 International License

Published

2017

31. Enzyme processivity changes with the extent of recalcitrant polysaccharide degradation

Author

Anne Grethe Hamre, Morten Sørlie, Silje Benedicte Lorentzen, and Priit Väljamäe

Subjects

Models, Molecular, Protein Conformation, Processivity, Biophysics, Chitin, Biology, Polysaccharide, Biochemistry, Acetylglucosamine, chemistry.chemical_compound, Hydrolysis, Structural Biology, Carbohydrate Conformation, Genetics, Glycoside hydrolase, Recalcitrant polysaccharides, Molecular Biology, Serratia marcescens, chemistry.chemical_classification, Chitinases, Substrate (chemistry), Glycosidic bond, Cell Biology, Solubility, chemistry, Carbohydrate conformation

Abstract

Polysaccharide depolymerization in nature is primarily accomplished by processive glycoside hydrolases which abstract single carbohydrate chains from polymer crystals and cleave glycosidic bonds without dissociating from the substrate after each catalytic event. Processivity is thought to conserve energy during enzymatic polysaccharide degradation. Herein, we compare two processive chitinases, ChiA and ChiB, one mutant, ChiB-W97A, and the endochitinase ChiC of the wellcharacterized chitinolytic machinery of Serratia marcescens by monitoring the extent of degradation on three different chitin substrates, and using the [(GlcNAc)2]/[GlcNAc] product ratio as a measure of processivity. The results show that the apparent processivity (Papp) greatly diminishes with the extent of degradation and confirm the hypothesis that Papp is limited by the length of obstacle free path on the substrate.

Published

2014

32. Antifungal effect of chito-oligosaccharides with different degrees of polymerization

Author

Md. Hafizur Rahman, Morten Sørlie, Arne Tronsmo, Linda Gordon Hjeljord, and Berit Bjugan Aam

Subjects

biology, technology, industry, and agriculture, Mucor piriformis, Germ tube, macromolecular substances, Plant Science, Horticulture, Degree of polymerization, biology.organism_classification, Chitosan, chemistry.chemical_compound, chemistry, Chitin, Biochemistry, Polymerization, In vivo, Agronomy and Crop Science, Botrytis cinerea

Abstract

Chitosan, obtained from chitin by partial N-deacetylation, shows little or no toxicity towards mammalian cells, is biodegradable, and non-allergenic. It is known that chitosan may have antifungal properties, but the effect of defined chitosan or chito-oligosaccharides (CHOS) with different degree of polymerization is not well known. The objective of this study was to produce CHOS with different DPn (average degree of polymerization) and determine the most effective DPn of chitosan and CHOS against Botrytris cinerea Pers. Ex Fr. and Mucor piriformis Fischer. In vitro testing showed that CHOS of DPn 23 and 40 had the highest germination inhibition against the tested pathogens. The original chitosan (DPn 206) and a collection of short CHOS (degree of polymerization of 3–10) were significantly (P < 0.01) less effective than CHOS of DPn 23 and 40. M. piriformis M119J showed the most abnormal swelling in presence of CHOS DPn 40, but all abnormally swollen conidia showed further germ tube elongation. In vivo testing showed that CHOS DPn 23 was the most effective in reducing flower infection by two isolates of B. cinerea. Our results show that CHOS inhibit fungal germination and growth and that the effect depends highly on the level of polymerization of the oligomers.

Published

2014

33. Comparative Study of Two Chitin-Active and Two Cellulose-Active AA10-Type Lytic Polysaccharide Monooxygenases

Author

Sophanit Mekasha, Vincent G. H. Eijsink, Gustav Vaaje-Kolstad, Kerstin Andersson, Zarah Forsberg, Åsmund K. Røhr, and Morten Sørlie

Subjects

Stereochemistry, Molecular Sequence Data, Bacillus, Chitin, Streptomyces coelicolor, Sequence alignment, Polysaccharide, Biochemistry, Mixed Function Oxygenases, Fungal Proteins, chemistry.chemical_compound, Bacterial Proteins, Catalytic Domain, Amino Acid Sequence, Cellulose, Peptide sequence, Serratia marcescens, chemistry.chemical_classification, biology, Active site, Substrate (chemistry), Monooxygenase, Enzyme, chemistry, biology.protein, Thermoascus, Sequence Alignment, Copper

Abstract

Lytic polysaccharide monooxygenases (LPMOs), found in family 9 (previously GH61), family 10 (previously CBM33), and the newly discovered family 11 of auxiliary activities (AA) in the carbohydrate-active enzyme classification system, are copper-dependent enzymes that oxidize sp(3)-carbons in recalcitrant polysaccharides such as chitin and cellulose in the presence of an external electron donor. In this study, we describe the activity of two AA10-type LPMOs whose activities have not been described before and we compare in total four different AA10-type LPMOs with the aim of finding possible correlations between their substrate specificities, sequences, and EPR signals. EPR spectra indicate that the electronic environment of the copper varies within the AA10 family even though amino acids directly interacting with the copper atom are identical in all four enzymes. This variation seems to be correlated to substrate specificity and is likely caused by sequence variation in areas that affect substrate binding geometry and/or by variation in a cluster of conserved aromatic residues likely involved in electron transfer. Interestingly, EPR signals for cellulose-active AA10 enzymes were similar to those previously observed for cellulose-active AA9 enzymes. Mutation of the conserved phenylalanine positioned in close proximity to the copper center in AA10-type LPMOs to Tyr (the corresponding residue in most AA9-type LPMOs) or Ala, led to complete or partial inactivation, respectively, while in both cases the ability to bind copper was maintained. Moreover, substrate binding affinity and degradation ability seemed hardly correlated, further emphasizing the crucial role of the active site configuration in determining LPMO functionality.

Published

2014

34. Analysis of productive binding modes in the human chitotriosidase

Author

Vincent G. H. Eijsink, Kristine Bistrup Eide, Morten Sørlie, Anne Line Norberg, and Anne Rita Lindbom

Subjects

Models, Molecular, Transglycosylation, Protein Conformation, Stereochemistry, Biophysics, Oligosaccharides, Chitin, Biology, Biochemistry, Pichia, Substrate Specificity, Structural Biology, Genetics, Humans, Endo-activity, Molecular Biology, Strong binding, Chitotriosidase, Binding affinities, Binding Sites, Cell Biology, Kinetics, Hexosaminidases, Chitinase, biology.protein, Human chitinase

Abstract

Human chitotriosidase (HCHT) is a family 18 chitinase that is an innate part of the immune system. We have mapped preferred productive binding modes of chito-oligosaccharide substrates to HCHT and the data show that HCHT has strong binding affinity in the +3 subsite. Moreover, HCHT shows anomer-specific binding affinities in subsites +2 and +3. These features could endorse HCHT with higher endo-activity and a higher transglycosylation potential.

Published

2013

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

Author

Åsmund K. Røhr, Maria Dimarogona, Finn Lillelund Aachmann, Gaston Courtade, Marita Preims, Mats Sandgren, Alfons K. G. Felice, Gustav Vaaje-Kolstad, Morten Sørlie, Reinhard Wimmer, Vincent G. H. Eijsink, and Roland Ludwig

Subjects

0301 basic medicine, Cellobiose dehydrogenase, Cytochrome, Stereochemistry, Mixed Function Oxygenases, Substrate Specificity, Fungal Proteins, 03 medical and health sciences, chemistry.chemical_compound, Binding site, Nuclear Magnetic Resonance, Biomolecular, Glucan, chemistry.chemical_classification, Fungal protein, Multidisciplinary, Binding Sites, biology, Neurospora crassa, Isothermal titration calorimetry, Glycosidic bond, Biological Sciences, Heme B, 030104 developmental biology, Biochemistry, chemistry, biology.protein, Carbohydrate Dehydrogenases, Copper

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. © 2016 The Authors. Published by National Academy of Sciences.

Published

2016

36. Cytosol protein regulation in H295R steroidogenesis model induced by the zearalenone metabolites, α- and β-zearalenol

Author

Silvio Uhlig, Erik Ropstad, Øyvind L. Busk, Caroline Frizzell, Steven Verhaegen, Lisa Connolly, and Morten Sørlie

Subjects

chemistry.chemical_classification, Quantitative proteomics, Proteins, Biology, Toxicology, Cell Line, Amino acid, Cytosol, chemistry.chemical_compound, Gene Expression Regulation, Biochemistry, chemistry, Protein regulation, Labelling, Stable isotope labeling by amino acids in cell culture, Humans, Zearalenone, Zeranol, Steroids, Protein Interaction Maps, Mycotoxin

Abstract

α- and β-zearalenol (α-ZOL and β-ZOL, respectively) are metabolites of the mycotoxin zearalenone (ZEN). All three individual mycotoxins have shown to be biological active i.e. being estrogenic and able to stimulate cellular proliferation albeit at different strengths. In this work, cytosol protein expression was determined by using stable-isotope labelling by amino acids in cell culture (SILAC) upon exposure of α-ZOL and β-ZOL to the steroidogenesis cell model H295R. A total of 14 and 5 individual proteins were found to be significantly regulated by α-ZOL and β-ZOL, respectively. Interestingly, there were no common protein regulations by the metabolites or the parent mycotoxin ZEN. Furthermore, the regulated proteins were assigned to networks and groups of actions that also differed from one another suggesting that the three individual mycotoxins may have unique biological activities.

Published

2012

37. Chitin oligosaccharide binding to a family GH19 chitinase from the moss Bryum coronatum

Author

Takayuki Ohnuma, Tamo Fukamizo, Tatsuya Fukuda, Noriko Kawamoto, Morten Sørlie, and Toki Taira

Subjects

chemistry.chemical_classification, biology, Mutant, Isothermal titration calorimetry, Cell Biology, Plasma protein binding, Oligosaccharide, Biochemistry, carbohydrates (lipids), chemistry.chemical_compound, Hydrolysis, Oligosaccharide binding, Chitin, chemistry, Chitinase, biology.protein, Molecular Biology

Abstract

Substrate binding of a family GH19 chitinase from a moss species, Bryum coronatum (BcChi-A, 22 kDa), which is smaller than the 26 kDa family GH19 barley chitinase due to the lack of several loop regions (‘loopless’), was investigated by oligosaccharide digestion, thermal unfolding experiments and isothermal titration calorimetry (ITC). Chitin oligosaccharides [β-1,4-linked oligosaccharides of N-acetylglucosamine with a polymerization degree of n, (GlcNAc)n, n = 3–6] were hydrolyzed by BcChi-A at rates in the order (GlcNAc)6 > (GlcNAc)5 > (GlcNAc)4 >> (GlcNAc)3. From thermal unfolding experiments using the inactive BcChi-A mutant (BcChi-A-E61A), in which the catalytic residue Glu61 is mutated to Ala, we found that the transition temperature (Tm) was elevated upon addition of (GlcNAc)n (n = 2–6) and that the elevation (ΔTm) was almost proportional to the degree of polymerization of (GlcNAc)n. ITC experiments provided the thermodynamic parameters for binding of (GlcNAc)n (n = 3–6) to BcChi-A-E61A, and revealed that the binding was driven by favorable enthalpy changes with unfavorable entropy changes. The change in heat capacity (ΔCp°) for (GlcNAc)6 binding was found to be relatively small (−105 ± 8 cal·K−1·mol−1). The binding free energy changes for (GlcNAc)6, (GlcNAc)5, (GlcNAc)4 and (GlcNAc)3 were determined to be −8.5, −7.9, −6.6 and −5.0 kcal·mol−1, respectively. Taken together, the substrate binding cleft of BcChi-A consists of at least six subsites, in contrast to the four-subsites binding cleft of the ‘loopless’ family 19 chitinase from Streptomyces coelicolor. Database Chitinase, EC 3.2.1.14

Published

2011

38. Cleavage of cellulose by a CBM33 protein

Author

Anne C. Bunæs, Zarah Forsberg, Gustav Vaaje-Kolstad, Yngve Stenstrøm, Svein Jarle Horn, Morten Sørlie, Alasdair Mackenzie, Vincent G. H. Eijsink, and Bjørge Westereng

Subjects

Fungal protein, biology, Chemistry, Streptomyces coelicolor, Cellulase, biology.organism_classification, Biochemistry, chemistry.chemical_compound, Hydrolysis, Chitin, Cleave, biology.protein, Glycoside hydrolase, Cellulose, Molecular Biology

Abstract

Bacterial proteins categorized as family 33 carbohydrate-binding modules (CBM33) were recently shown to cleave crystalline chitin, using a mechanism that involves hydrolysis and oxidation. We show here that some members of the CBM33 family cleave crystalline cellulose as demonstrated by chromatographic and mass spectrometric analyses of soluble products released from Avicel or filter paper on incubation with CelS2, a CBM33-containing protein from Streptomyces coelicolor A3(2). These enzymes act synergistically with cellulases and may thus become important tools for efficient conversion of lignocellulosic biomass. Fungal proteins classified as glycoside hydrolase family 61 that are known to act synergistically with cellulases are likely to use a similar mechanism.

Published

2011

39. Concurrent enzyme reactions and binding events for chitinases interacting with chitosan oligosaccharides monitored by high resolution mass spectrometry

Author

F. Henning Cederkvist, Morten Sørlie, Michael Mormann, Martin Froesch, Vincent G. H. Eijsink, and Jasna Peter-Katalinić

Subjects

chemistry.chemical_classification, Stereochemistry, Electrospray ionization, Oligosaccharide, Condensed Matter Physics, Mass spectrometry, Fourier transform ion cyclotron resonance, Oligosaccharide binding, chemistry, Biochemistry, Mutant protein, Glycoside hydrolase, Physical and Theoretical Chemistry, Instrumentation, Spectroscopy, Ion cyclotron resonance

Abstract

High resolution nanoelectrospray ionization Fourier-transform ion cyclotron resonance mass spectrometry was used to monitor formation of non-covalent complexes between chitinase B, a family 18 glycoside hydrolase, and hetero-chitooligosaccharides. Besides anticipated productive binding followed by glycoside hydrolysis, additional processes like transglycosylation, non-productive binding of potential inhibitors, and oxidation were detected by analysis of multiple non-covalent enzyme–ligand complexes as well as free oligosaccharide ions. Upon mutation of Asp142, responsible for binding and activation of the N -acetylgroup of the -1 sugar for nucleophilic attack on the anomeric carbon, a significant decrease of catalytic activity in the mutant protein was accompanied by drastic changes in oligosaccharide binding preferences and by changed reaction product profiles. The analysis of complex “mixed” enzyme–ligand interactions with unprecedented accuracy and level of detail also provided direct evidence for the occurrence of transglycosylation, leading to the formation of longer oligosaccharides in the reactions with both wild-type ChiB and its D142N mutant. This direct monitoring strategy of distinct types of enzyme–ligand interactions to identify in parallel all products of main and side reactions represents a general approach made possible by MS of ultrahigh resolution and mass accuracy.

Published

2011

40. Mutational Effects on Transglycosylating Activity of Family 18 Chitinases and Construction of a Hypertransglycosylating Mutant

Author

Morten Sørlie, Henrik Zakariassen, Maje Jøranli, Vincent G. H. Eijsink, and Mona Cecilie Hansen

Subjects

chemistry.chemical_classification, Aspartic Acid, Glycosylation, biology, Stereochemistry, Hydrolysis, Chitinases, Mutant, Oligosaccharides, biology.organism_classification, Biochemistry, Substrate Specificity, Enzyme, Bacterial Proteins, chemistry, Catalytic cycle, Catalytic Domain, Multigene Family, Enzyme Stability, Serratia marcescens, Mutagenesis, Site-Directed, Point Mutation, Asparagine

Abstract

Enzymatic features that determine transglycosylating activity have been investigated through site-directed mutagenesis studies on two family 18 chitinases, ChiA and ChiB from Serratia marcescens, with inherently little transglycosylation activity. The activity was monitored for the natural substrate (GlcNAc)(4) using mass spectrometry and HPLC. Mutation of the middle Asp in the diagnostic DxDxE motif, which interacts with the catalytic Glu during the catalytic cycle, yielded the strongly transglycosylating mutants ChiA-D313N and ChiB-D142N, respectively. Mutation of the same Asp(313/142) to Ala or the mutation of Asp(311/140) to either Asn or Ala had no or much smaller effects on transglycosylating activity. Mutation of Phe(396) in the +2 subsite of ChiA-D313N to Trp led to a severalfold increase in transglycosylation rate while replacement of aromatic residues with Ala in the aglycon (sugar acceptor-binding) subsites of ChiA-D313N and ChiB-D142N led to a clear reduction in transglycosylating activity. Taken together, these results show that the transglycosylation properties of family 18 chitinases may be manipulated by mutations that affect the configuration of the catalytic machinery and the affinity for sugar acceptors. The hypertransglycosylating mutant ChiA-D313N-F396W may find applications for synthetic purposes.

Published

2011

41. An Oxidative Enzyme Boosting the Enzymatic Conversion of Recalcitrant Polysaccharides

Author

Gustav Vaaje-Kolstad, Hong Zhai, Vincent G. H. Eijsink, Svein Jarle Horn, Bjørge Westereng, Zhanliang Liu, and Morten Sørlie

Subjects

Cations, Divalent, Oligosaccharides, Chitin, Oxygen Isotopes, Polysaccharide, Enzyme catalysis, chemistry.chemical_compound, Bacterial Proteins, Biotransformation, Oxidative enzyme, Biomass, Enzyme Inhibitors, Cellulose, Chromatography, High Pressure Liquid, Edetic Acid, Serratia marcescens, chemistry.chemical_classification, Binding Sites, Multidisciplinary, biology, Chemistry, Hydrolysis, Chitinases, Intracellular Signaling Peptides and Proteins, Enzyme assay, Enzyme, Solubility, Biochemistry, Isotope Labeling, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Biocatalysis, biology.protein, Carrier Proteins, Oxidation-Reduction

Abstract

Polysaccharide Breakdown One of the current challenges in the biofuels industry is achieving efficient bioconversion of complex polysaccharides like cellulose and chitin. Recently, chitin-binding proteins (CBPs) have been identified that potentiate chitin hydrolysis. Now, Vaaje-Kolstad et al. (p. 219 ) show that a CBP from the chitinolytic bacterium Serratia marcescens appears to catalyze an oxygenase reaction on the surface of crystallized chitin, leading to chain breakage and generating oxidized ends that can be degraded by chitinases. A structurally similar enzyme, GH61, may play a similar role in the degradation of cellulose.

Published

2010

42. Effect of enzyme processivity on the efficacy of a competitive chitinase inhibitor

Author

Henrik Zakariassen, Shohei Sakuda, Morten Sørlie, Gustav Vaaje-Kolstad, Laila Klemetsen, Vincent G. H. Eijsink, and Kjell M. Vårum

Subjects

chemistry.chemical_classification, Polymers and Plastics, biology, Organic Chemistry, Processivity, biology.organism_classification, Serratia, chemistry.chemical_compound, Non-competitive inhibition, Enzyme, Biochemistry, chemistry, Chitin, Chitinase, Serratia marcescens, Materials Chemistry, biology.protein, Glycoside hydrolase

Abstract

Many glycoside hydrolases, such as chitinases and cellulases, degrade polysaccharides in a processive manner. Inhibition of chitinases is of great interest, because chitin-metabolizing pathogenic organisms such as certain fungi, insects and nematodes need chitinase activity for survival. Here we show how the processivity and the directionality of two chitinases, chitinase A (ChiA) and B (ChiB) from Serratia marcescens, affects the practical inhibition efficacy (IC50) of allosamidin, a general competitive inhibitor of family 18 chitinases. The results show that there is a clear negative correlation between processivity and the efficiency of competitive inhibition, and that this effect of processivity (i.e. reducing inhibitor efficacy) is largest when allosamidin binds to those enzyme subsites that interact with the polymeric part of the substrate. Besides providing further insight into the processivity and directionality of the two Serratia enzymes, these results reveal important aspects of ligand binding that should be taken into account when designing inhibitors of processive enzymes.

Published

2010

43. Kinetics of H2O2-driven degradation of chitin by a bacterial lytic polysaccharide monooxygenase

Author

Zarah Forsberg, Piret Kuusk, Silja Kuusk, Priit Väljamäe, Morten Sørlie, Bastien Bissaro, and Vincent G. H. Eijsink

Subjects

0301 basic medicine, chemistry.chemical_classification, 010405 organic chemistry, Glycosidic bond, Cell Biology, Monooxygenase, Polysaccharide, 01 natural sciences, Biochemistry, 0104 chemical sciences, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Reaction rate constant, Enzyme, chemistry, Chitin, Organic chemistry, Enzyme kinetics, Cellulose, Molecular Biology

Abstract

Lytic polysaccharide monooxygenases (LPMOs) catalyze the oxidative cleavage of glycosidic bonds in recalcitrant polysaccharides, such as cellulose and chitin, and are of interest in biotechnological utilization of these abundant biomaterials. It has recently been shown that LPMOs can use H2O2, instead of O2, as a cosubstrate. This peroxygenase-like reaction by a monocopper enzyme is unprecedented in nature and opens new avenues in chemistry and enzymology. Here, we provide the first detailed kinetic characterization of chitin degradation by the bacterial LPMO chitin-binding protein CBP21 using H2O2 as cosubstrate. The use of 14C-labeled chitin provided convenient and sensitive detection of the released soluble products, which enabled detailed kinetic measurements. The kcat for chitin oxidation found here (5.6 s−1) is more than an order of magnitude higher than previously reported (apparent) rate constants for reactions containing O2 but no added H2O2. The kcat/Km for H2O2-driven degradation of chitin was on the order of 106 m−1 s−1, indicating that LPMOs have catalytic efficiencies similar to those of peroxygenases. Of note, H2O2 also inactivated CBP21, but the second-order rate constant for inactivation was about 3 orders of magnitude lower than that for catalysis. In light of the observed CBP21 inactivation at higher H2O2 levels, we conclude that controlled generation of H2O2 in situ seems most optimal for fueling LPMO-catalyzed oxidation of polysaccharides.

Published

2018

44. Signatures of activation parameters reveal substrate-dependent rate determining steps in polysaccharide turnover by a family 18 chitinase

Author

Henrik Zakariassen, Vincent G. H. Eijsink, and Morten Sørlie

Subjects

chemistry.chemical_classification, Polymers and Plastics, Organic Chemistry, Substrate (chemistry), macromolecular substances, Processivity, Polysaccharide, Rate-determining step, Catalysis, chemistry.chemical_compound, Hydrolysis, Chitin, chemistry, Biochemistry, Materials Chemistry, Glycoside hydrolase

Abstract

Glycoside hydrolases play an important role in the degradation of biomass such as cellulose and chitin. Many of these enzymes act by a processive mechanism, which is generally considered favorable because it improves substrate-accessiblity. Recently we showed that this only applies to insoluble substrates. Towards more soluble and accessible substrates, processivity may in fact reduce the catalytic activity. Here, we describe kinetic studies showing how the type of substrate, insoluble or soluble, affects the activation parameters and rate determining steps for catalysis by the processive two-domain chitinase A (ChiA) from Serratia marcescens. The activation parameters show a large entropic activation barrier, indicative of a bimolecular (associative) rate determining step, for the degradation of insoluble crystalline β-chitin. For the water-soluble polymeric chitin-derivative chitosan, the rate determining step is associated with product-displacement and release. Furthermore, the degree of processivity is reflected in the activation parameters for chitosan hydrolysis; increase in processivity results in increase in activation enthalpy change and decrease in activation entropy change.

Published

2010

45. Production of Chitooligosaccharides and Their Potential Applications in Medicine

Author

Berit Bjugan Aam, Kjell M. Vårum, Anne Line Norberg, Ellinor Bævre Heggset, Morten Sørlie, and Vincent G. H. Eijsink

Subjects

Antifungal, medicine.drug_class, Chitinases, chitooligosaccharide (CHOS), Oligosaccharides, Pharmaceutical Science, Chitin, Review, Biology, Drug formulations, lcsh:Biology (General), Biochemistry, chitinase, Drug Discovery, medicine, Humans, Tumor growth inhibition, chitosanase, chitosan, application, lcsh:QH301-705.5, Pharmacology, Toxicology and Pharmaceutics (miscellaneous), Antibacterial agent

Abstract

Chitooligosaccharides (CHOS) are homo- or heterooligomers of N-acetylglucosamine and D-glucosamine. CHOS can be produced using chitin or chitosan as a starting material, using enzymatic conversions, chemical methods or combinations thereof. Production of well-defined CHOS-mixtures, or even pure CHOS, is of great interest since these oligosaccharides are thought to have several interesting bioactivities. Understanding the mechanisms underlying these bioactivities is of major importance. However, so far in-depth knowledge on the mode-of-action of CHOS is scarce, one major reason being that most published studies are done with badly characterized heterogeneous mixtures of CHOS. Production of CHOS that are well-defined in terms of length, degree of N-acetylation, and sequence is not straightforward. Here we provide an overview of techniques that may be used to produce and characterize reasonably well-defined CHOS fractions. We also present possible medical applications of CHOS, including tumor growth inhibition and inhibition of T(H)2-induced inflammation in asthma, as well as use as a bone-strengthener in osteoporosis, a vector for gene delivery, an antibacterial agent, an antifungal agent, an anti-malaria agent, or a hemostatic agent in wound-dressings. By using well-defined CHOS-mixtures it will become possible to obtain a better understanding of the mechanisms underlying these bioactivities.

Published

2010

46. The Roles of Three Serratia marcescens Chitinases in Chitin Conversion Are Reflected in Different Thermodynamic Signatures of Allosamidin Binding

Author

Vincent G. H. Eijsink, Jamil Baban, Morten Sørlie, Salima Fjeld, and Shohei Sakuda

Subjects

Stereochemistry, Chitin, Crystallography, X-Ray, Acetylglucosamine, Protein structure, Catalytic Domain, Materials Chemistry, Enzyme Inhibitors, Physical and Theoretical Chemistry, Serratia marcescens, chemistry.chemical_classification, biology, Chitinases, Solvation, Isothermal titration calorimetry, Conformational entropy, biology.organism_classification, Protein Structure, Tertiary, Surfaces, Coatings and Films, Enzyme, chemistry, Biochemistry, Chitinase, biology.protein, Thermodynamics, Trisaccharides, Entropy (order and disorder)

Abstract

Binding of allosamidin to the three family 18 chitinases of Serratia marcescens has been studied using isothermal titration calorimetry (ITC). Interestingly, the thermodynamic signatures of allosamidin binding were different for all three chitinases. At pH 6.0, chitinase A (ChiA) binds allosamidin with a K(d) value of 0.17 +/- 0.06 microM where the main part of the driving force is due to enthalpic change (DeltaH(r) degrees = -6.2 +/- 0.2 kcal/mol) and less to entropic change (-TDeltaS(r) degrees = -3.2 kcal/mol). A large part of DeltaH is due to allosamidin stacking with Trp(167) in the -3 subsite. Binding of allosamidin to both chitinase B (ChiB) (K(d) = 0.16 +/- 0.04 microM) and chitinase C (ChiC) (K(d) = 2.0 +/- 0.2 microM) is driven by entropy (DeltaH(r) degrees = 3.8 +/- 0.2 kcal/mol and -TDeltaS(r) degrees = -13.2 kcal/mol for ChiB and DeltaH(r) degrees = -0.6 +/- 0.1 and -TDeltaS(r) degrees = -7.3 kcal/mol for ChiC). For ChiC, the entropic term is dominated by changes in solvation entropy (DeltaS(conf) = 1 cal/K.mol and DeltaS(solv) = 31 cal/K.mol), while, for ChiB, changes in conformational entropy dominate (DeltaS(conf) = 37 cal/K x mol and DeltaS(solv) = 15 cal/K x mol). Corresponding values for ChiA are DeltaS(conf) = 4 cal/K x mol and DeltaS(solv) = 15 cal/K x mol. These remarkable differences in binding parameters reflect the different architectures of the catalytic centers in these enzymes that are adapted to different types of actions: ChiA and ChiB are processive enzymes that move in opposite directions, meaning that allosamidin binds in to "product" subsites in ChiB, while it binds to polymer-binding subsites in ChiA. The values for ChiC are compatible with this enzyme being a nonprocessive endochitinase with a much more open and solvated substrate-binding-site cleft.

Published

2010

47. Inhibition of a family 18 chitinase by chitooligosaccharides

Author

Morten Sørlie, Kjell M. Vårum, Marthe P. Parmer, F. Henning Cederkvist, and Vincent G. H. Eijsink

Subjects

chemistry.chemical_classification, Polymers and Plastics, biology, Stereochemistry, Organic Chemistry, Active site, Glycosidic bond, Degree of polymerization, biology.organism_classification, Enzyme, Biochemistry, chemistry, DNA glycosylase, Acetylation, Serratia marcescens, Chitinase, Materials Chemistry, biology.protein

Abstract

Inhibition of family 18 chitinases is emerging as a target for pest and fungal control as well as asthma and inflammatory therapy. To this regard, it is desirable to have access to non-toxic inhibitors that are easy to produce, and have high specificity and efficiency. Chitooligosaccharides (CHOS) that are partially N-acetylated have the potential to fulfill these requirements. In this work, a high molecular weight chitosan with a degree of acetylation of 0.65 was enzymatically degraded by chitinase C, a family 18 endochitinase from Serratia marcescens, to a degree of scission (the fraction of cleaved glycosidic linkages) of 0.2. The resulting CHOS were purified with respect to degree of polymerization (DP). CHOS of DP 5, 6, and 8, respectively, were allowed to interact with another type of family 18 chitinase from S. marcescens, chitinase B, used as a model enzyme for a group of family 18 chitinases with deep active site grooves that includes human enzymes. Products obtained after 7 h were isolated and their structures were determined using mass spectrometry. The IC50-values of the resulting CHOS solutions for ChiB were in the lower micromolar range (15–18 μM).

Published

2008

48. Modulation of Lck Function through Multisite Docking to T Cell-specific Adapter Protein

Author

Lise Koll, Stine Granum, Vibeke Sundvold-Gjerstad, Tor Lea, Burkhard Fleckenstein, Anne Spurkland, Thorny Cecilie Bie Andersen, Tone Berge, Morten Sørlie, and Marit Jørgensen

Subjects

CD4-Positive T-Lymphocytes, Phosphopeptides, T cell, Receptors, Antigen, T-Cell, chemical and pharmacologic phenomena, Ligands, SH2 domain, Biochemistry, Cell Line, src Homology Domains, Jurkat Cells, chemistry.chemical_compound, medicine, Humans, Phosphorylation, Molecular Biology, Adaptor Proteins, Signal Transducing, Chemistry, Phosphopeptide, C-terminus, Signal transducing adaptor protein, hemic and immune systems, Tyrosine phosphorylation, Cell Biology, Cell biology, medicine.anatomical_structure, Lymphocyte Specific Protein Tyrosine Kinase p56(lck), Tyrosine, biological phenomena, cell phenomena, and immunity, Protein Binding, Proto-oncogene tyrosine-protein kinase Src

Abstract

T cell-specific adapter protein (TSAd), encoded by the SH2D2A gene, interacts with Lck through its C terminus and thus modulates Lck activity. Here we mapped Lck phosphorylation and interaction sites on TSAd and evaluated their functional importance. The three C-terminal TSAd tyrosines Tyr(280), Tyr(290), and Tyr(305) were phosphorylated by Lck and functioned as docking sites for the Lck Src homology 2 (SH2) domain. Binding affinities of the TSAd Tyr(P)(280) and Tyr(P)(290) phosphopeptides to the isolated Lck SH2 domain were similar to that observed for the Lck Tyr(P)(505) phosphopeptide, whereas the TSAd Tyr(P)(305) peptide displayed a 10-fold higher affinity. The proline-rich Lck SH3-binding site on TSAd as well as the Lck SH2 domain were required for efficient tyrosine phosphorylation of TSAd by Lck. Interaction sites on TSAd for both Lck SH2 and Lck SH3 were necessary for TSAd-mediated modulation of proximal TCR signaling events. We found that 20-30% of TSAd molecules are phosphorylated in activated T cells and that the proportion of TSAd to Lck molecules in such cells is approximately 1:1. Therefore, in activated T cells, a considerable number of Lck molecules may potentially be engaged by TSAd. In conclusion, Lck binds to TSAd prolines and phosphorylates and interacts with the three C-terminal TSAd tyrosines. We propose that through multivalent interactions with Lck, TSAd diverts Lck from phosphorylating other substrates, thus modulating its functional activity through substrate competition.

Published

2008

49. Natural substrate assay for chitinases using high-performance liquid chromatography: A comparison with existing assays

Author

Vincent G. H. Eijsink, Bjørnar Synstad, Inger-Mari Krokeide, Sigrid Gåseidnes, Svein Jarle Horn, and Morten Sørlie

Subjects

Stereochemistry, Mutant, Kinetics, Biophysics, Oligosaccharides, Chitin, Biochemistry, High-performance liquid chromatography, Substrate Specificity, chemistry.chemical_compound, Amide, Bioassay, Molecular Biology, Chromatography, High Pressure Liquid, Serratia marcescens, Chromatography, biology, Chemistry, Chitinases, Substrate (chemistry), Cell Biology, biology.organism_classification, Mutation, Chitinase, biology.protein, Biological Assay

Abstract

The determination of kinetic parameters of chitinases using natural substrates is difficult due to low K(m) values, which require the use of low substrate concentrations that are hard to measure. Using the natural substrate (GlcNAc)(4), we have developed an assay for the determination of k(cat) and K(m)values of chitinases. Product concentrations as low as 0.5 microM were detected using normal-phase high-performance liquid chromatography (HPLC) with an amide 80 column (0.20 x 25 cm) using spectrophotometric detection at 210 nm. By means of this assay, k(cat) and K(m)values for chitinases A (ChiA) and B (ChiB) of Serratia marcescens were found to be 33+/-1s(-1) and 9+/-1 microM and 28+/-2s(-1) and 4+/-2 microM, respectively. For ChiB, these values were compared to those found with commonly used substrates where the leaving group is a (nonnatural) chromophore, revealing considerable differences. For example, assays with 4-methylumbelliferyl-(GlcNAc)(2) yielded a k(cat) value of 18+/-2s(-1) and a K(m) value of 30+/-6 microM. For two ChiB mutants containing a Trp --> Ala mutation in the +1 or +2 subsites, the natural substrate and the 4-methylumbelliferyl-(GlcNAc)(2) assays yielded rather similar K(m) values (5-fold difference at most) but showed dramatic differences in k(cat) values (up to 90-fold). These results illustrate the risk of using artificial substrates for characterization of chitinases and, thus, show that the new HPLC-based assay is a valuable tool for future chitinase research.

Published

2007

50. The role of active site aromatic residues in substrate degradation by the human chitotriosidase

Author

Linn Wilhelmsen Stockinger, Anne Tøndervik, Anna Lewin, Kristine Bistrup Eide, Vincent G. H. Eijsink, and Morten Sørlie

Subjects

0301 basic medicine, Stereochemistry, Biophysics, Chitin, Biochemistry, Analytical Chemistry, Substrate Specificity, 03 medical and health sciences, chemistry.chemical_compound, Amino Acids, Aromatic, Catalytic Domain, TIM barrel, Aromatic amino acids, Humans, Glycoside hydrolase, Enzyme kinetics, Molecular Biology, Glycoside hydrolase family 18, Chitosan, 030102 biochemistry & molecular biology, biology, Chemistry, Active site, Molecular Weight, 030104 developmental biology, Hexosaminidases, Chitinase, Mutation, biology.protein

Abstract

Human chitotriosidase (HCHT) is a glycoside hydrolase family 18 chitinase synthesized and secreted in human macrophages thought be an innate part of the human immune system. It consists of a catalytic domain with the (β/α)8 TIM barrel fold having a large area of solvent-exposed aromatic amino acids in the active site and an additional family 14 carbohydrate-binding module. To gain further insight into enzyme functionality, especially the effect of the active site aromatic residues, we expressed two variants with mutations in subsites on either side of the catalytic acid, subsite -3 (W31A) and +2 (W218A), and compared their catalytic properties on chitin and high molecular weight chitosans. Exchange of Trp to Ala in subsite -3 resulted in a 12-fold reduction in extent of degradation and a 20-fold reduction in kcat(app) on chitin, while the values are 5-fold and 10-fold for subsite +2. Moreover, aromatic residue mutation resulted in a decrease of the rate of chitosan degradation contrasting previous observations for bacterial family 18 chitinases. Interestingly, the presence of product polymers of 40 sugar moieties and higher starts to disappear already at 8% degradation for HCHT50-W31A. Such behavior contrast that of the wild type and HCHT-W218A and resembles the action of endo-nonprocessive chitinases.

Published

2015