Global ETD Search

1	Elucidation of structure and substrate-specificity of a glycoside hydrolase from family 81 and a carbohydrate binding module from family 56 Fillo, Alexander 24 December 2014 (has links) The degradation of carbohydrates is essential to many biological processes such as cell wall remodelling, host-pathogen defense, and energy synthesis in the form of ATP. Several of these processes utilize carbohydrate-active enzymes to accomplish these goals. Studying the degradation of polysaccharides by carbohydrate-active enzymes synthesized by microbes has allowed us to further understand biomass conversion. A portion of these polysaccharides consists of β-1,3-linked glucose (i.e. β-1,3-glucan), which is found in plants, fungi, and brown macroalgae. The hydrolysis of β-1,3-glycosidic linkages is catalyzed by β-1,3-glucanases, which are present in six different glycoside hydrolase (GH) families: 16, 17, 55, 64, 81, and 128. These enzymes play important biological roles including carbon utilization, cell wall modeling, and pathogen defense. This study focuses on a gene from Bacillus halodurans encoding for a multi-modular protein (BhLam81) consisting of a glycoside hydrolase from family 81 (BhGH81), a carbohydrate-binding module (CBM) from family 6 (BhCBM6), and a CBM from family 56 (BhCBM56). Previously, thorough structural and substrate-specific characterization has been carried out on BhCBM6. This CBM binds the non-reducing end of β-1,3-glucan. A member of CBM family 56 has been shown to recognize and bind the insoluble β-1,3-glucan, pachyman, however it is structurally uncharacterized. A glycoside hydrolase belonging to family 81 from Saccharomyces cerevisiae has been previously shown to degrade the β-1,3-glucans, laminarin and pachyman, however the structure of this enzyme was not determined. Recently, a member of GH family 81 has been structurally characterized; however, substrate-specificity was not determined in that study. Therefore, this study concentrated on two goals: Determining the substrate-specificity of BhGH81 and BhCBM56, and solving the structure of BhGH81 and BhCBM56 in order to gain insight into the molecular details of how they recognize and act on their substrate(s). The deoxyribonucleic acid (DNA) encoding for these modules were dissected by restriction digest from B. halodurans genomic DNA and recombinantly expressed in Escherichia coli (E. coli) as separate constructs. Both BhGH81 and BhCBM56 were purified and their crystal structures obtained. BhGH81 and BhCBM56 were solved to 2.5 Å resolution by single-wavelength anomalous dispersion (SAD) and to 1.7 Å resolution by multi-wavelength anomalous dispersion (MAD), respectively. In order to determine the substrate-specificity of BhGH81 and BhCBM56 and speculate on the molecular details of how they recognize and act on their substrate(s), substrate-specificity tests were combined with structural analysis for both of these modules. By using qualitative depletion assays, quantitative depletion assays, and affinity electrophoresis, it was revealed that BhCBM56 binds both insoluble and soluble β-1,3-glucan. The crystal structure of BhCBM56 revealed that it is a β-sandwich composed of two antiparallel β-sheets consisting of five β-strands each. By comparing BhCBM56 to a β-1,3-glucan binding protein from Plodia interpunctella (βGRP) a putative substrate-binding cleft on the concave side of the β-sandwich created by a platform of hydrophobic residues surrounded by several polar and charged residues was revealed. This comparison also allowed for speculation of the amino acids (W1015, H965, and D963) that are potentially essential for recognition of β-1,3-glucan substrates by BhCBM56. Activity of BhGH81 on β-1,3-glucans was confirmed by both thin-layer chromatography and product analysis using high performance anion exchange chromatography. The high performance anion exchange chromatography of BhGH81 hydrolysis suggested it has both exo and endo modes of action. The crystal structure of BhGH81 revealed that it consists of domains A, B, and C: A β-sandwich domain (A), a linker domain (B), and an (α/α)6-barrel domain (C). This structure revealed a putative substrate-binding cleft on one side of the (α/α)6-barrel with a blind canyon active site topology. It also revealed two putative catalytic residues, E542 and E546. All GHs from family 81 characterized so far, hydrolyze β-1,3-glucan in an endo acting manner. By comparing the structure of BhGH81 acquired in this study to a cellulase from Thermobifida fusca, which has an endo-processive mode of action, we can speculate that BhGH81 also has an endo-processive mode of action. The structural and biochemical analysis of BhGH81 and BhCBM56 in this study has aided in further understanding the molecular details both GH family 81 and CBM family 56 proteins, as well as the degradation of β-1,3-glucan by multimodular enzymes. Understanding these molecular details could be important for industrial applications such as, engineering a microbial platform for more efficient biofuel production. / Graduate beta-1,3-glucan glycoside hydrolase carbohydrate binding module
2	Interaction analysis between lignin and carbohydrate-binding module of cellobiohydrolase I from Trichoderma reesei / Trichoderma reesei由来セロビオヒドロラーゼIの糖質結合モジュールとリグニン間の相互作用解析 Tokunaga, Yuki 23 March 2021 (has links) 京都大学 / 新制・課程博士 / 博士(農学) / 甲第23238号 / 農博第2445号 / 新制\|\|農\|\|1083(附属図書館) / 学位論文\|\|R3\|\|N5328(農学部図書室) / 京都大学大学院農学研究科応用生命科学専攻 / (主査)教授渡邊隆司, 教授植田充美, 教授梅澤俊明 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM Biorefinery Lignin Cellulase Carbohydrate-binding module Nuclear Magnetic Resonance 610
3	Structural and functional studies of interactions between [beta]-1,3-glucan and the N-terminal domains of [beta]-1,3-glucan recognition proteins involved in insect innate immunity Dai, Huaien January 1900 (has links) Doctor of Philosophy / Department of Biochemistry / Ramaswamy Krishnamoorthi / Insect [beta]-1,3-glucan recognition protein ([beta]GRP), a soluble receptor in the hemolymph, binds to the surfaces of bacteria and fungi and activates serine protease cascades that promote destruction of pathogens by means of melanization or expression of antimicrobial peptides. Delineation of mechanistic details of these processes may help develop strategies to control insect-borne diseases and economic losses. Multi-dimensional nuclear magnetic resonance (NMR) techniques were employed to solve the solution structure of the Indian meal moth (Plodia interpunctella) [beta]GRP N-terminal domain (N-[beta]GRP), which is sufficient to activate the prophenoloxidase (proPO) pathway resulting in melanin formation. This is the first determined three-dimensional structure of N-[beta]GRP, which adopts an immunoglobulin fold. Addition of laminarin, a [beta]-1,3 and [beta]-1,6 link-containing glucose polysaccharide (∼6 kDa) that activates the proPO pathway, to N-[beta]GRP results in the loss of NMR cross-peaks from the backbone [subscript]1[subscript]5N-[subscript]1H groups of the protein, suggesting the formation of a large complex. Analytical ultracentrifugation (AUC) studies of formation of the N-[beta]GRP:laminarin complex show that ligand binding induces self-association of the protein-carbohydrate complex into a macro structure, likely containing six protein and three laminarin molecules (∼102 kDa). The macro complex is quite stable, as it does not undergo dissociation upon dilution to submicromolar concentrations. The structural model thus derived from this study for the N-[beta]GRP:laminarin complex in solution differs from the one in which a single N-[beta]GRP molecule has been proposed to bind to a triple-helical form of laminarin on the basis of a X-ray crystal structure of the N-[beta]GRP:laminarihexaose complex. AUC studies and phenoloxidase activation measurements made with designed mutants of N-[beta]GRP indicate that electrostatic interactions between the ligand-bound protein molecules contribute to the stability of the N-[beta]GRP:laminarin complex and that a decreased stability results in a reduction of proPO activation. These novel findings suggest that ligand-induced self-association of the [beta]GRP:[beta]-1,3-glucan complex may form a platform on a microbial surface for recruitment of downstream proteases, as a means of amplification of the pathogen recognition signal. In the case of the homolog of GNBPA2 from Anopheles gambiae, the malaria-causing Plasmodium carrier, multiligand specificity was characterized, suggesting a functional diversity of the immunoglobulin domain structure. Innate immunity 3-glucan Carbohydrate-binding module NMR AUC [beta]-13-glucan Biochemistry (0487) Biophysics (0786)
4	Caractérisation des a-L-arabinofuranosidases de la famille GH62 chez le champignon filamenteux Talaromyces versatilis (basionyme Penicillium funiculosum) et étude de leur impact, en association avec des xylanases, sur la dégradation d'arabinoxylane / Characterization of three GH62 α-L-arabinofuranosidases from Talaromyces versatilis (basionym Penicillium funiculosum) and impact study with xylanases on arabinoxylan degradation De la Mare, Marion 16 January 2014 (has links) La société Adisseo produit un cocktail d’enzymes hydrolytiques appelé Rovabio® Excel sécrété par un champignon filamenteux Talaromyces versatilis. Ce cocktail est utilisé comme additif alimentaire pour augmenter la digestibilité de complexes polysaccharidiques en nutrition animale et ainsi augmenter la valeur nutritionnelle des matières premières agricoles. Une récente étude protéomique de ce champignon (Guais et al., 2008) a révélé la présence d’un grand nombre d’arabinofuranosidases (ABFs) appartenant à différentes familles de glycosides hydrolases : 5 ABFs de la famille GH54, 3 ABFs de la famille GH62 et enfin une de la famille GH51. Un des objectifs de mes travaux de thèse a été le clonage, l’expression hétérologue (hôte lévurien Pichia pastoris) des 9 gènes codant pour ces 9 enzymes et la caractérisation complète de la famille GH62. La caractérisation des capacités d’hydrolyse des ABFs 54 et 62 a également été étudiée grâce à une technique d’empreintes d’hydrolyse enzymatique sur arabinoxylane de blé. Enfin, la dernière partie de mes travaux consistait à confectionner des mélanges d’enzymes hydrolytiques des différentes familles d’ABFs associés à des xylanases et de suivre l’efficacité de la dégradation de l’arabinoxylane insoluble grâce à l’utilisation d’un réacteur torique permettant l’acquisition d’images et l’analyse en ligne de la dégradation. Ces travaux sur le réacteur ont permis de mettre en évidence une synergie entre Abfs et Xylanases. / Adisseo produce and commercialize a hydrolytic enzymatic cocktail termed Rovabio and secreted by a filamentous fungus Talaromyces versatilis. This cocktail is used as feed additive for increased digestibility of complex polysaccharides in animal nutrition. A recent genomic study of this fungus revealed the presence of 5 arabinofuranosidases (Abfs) to family GH 54, 3 of GH 62 and 1 of GH51. The first aim of my thesis works was about cloning, heterologous overexpression (in pichia pastoris yeast) of this 9 genes encoding for this 9 enzymes and characterization of the family GH 62. Mode of action of ABFs 54 and 62s has been characterized by enzymatic fingerprinting analysis on wheat arabinoxylan. Then, last part was to design enzymatic cocktail with differents families of ABFs and Xylanases and test their impact on insoluble arabinoxylan hydrolysis with toric reactor. These works on reactor have bringing to light a synergy between ABFs and Xylanases Arabinofuranosidases Famille GH62 Arabinoxylane Carbohydrate binding module Réacteur torique Synergies Champignon filamenteux 664 572
5	On the engineering of proteins: methods and applications for carbohydrate-active enzymes Gullfot, Fredrika January 2010 (has links) This thesis presents the application of different protein engineering methods on enzymes and non-catalytic proteins that act upon xyloglucans. Xyloglucans are polysaccharides found as storage polymers in seeds and tubers, and as cross-linking glucans in the cell wall of plants. Their structure is complex with intricate branching patterns, which contribute to the physical properties of the polysaccharide including its binding to and interaction with other glucans such as cellulose. One important group of xyloglucan-active enzymes is encoded by the GH16 XTH gene family in plants, including xyloglucan endo-transglycosylases (XET) and xyloglucan endo-hydrolases (XEH). The molecular determinants behind the different catalytic routes of these homologous enzymes are still not fully understood. By combining structural data and molecular dynamics (MD) simulations, interesting facts were revealed about enzyme-substrate interaction. Furthermore, a pilot study was performed using structure-guided recombination to generate a restricted library of XET/XEH chimeras. Glycosynthases are hydrolytically inactive mutant glycoside hydrolases (GH) that catalyse the formation of glycosidic linkages between glycosyl fluoride donors and glycoside acceptors. Different enzymes with xyloglucan hydrolase activity were engineered into glycosynthases, and characterised as tools for the synthesis of well-defined homogenous xyloglucan oligo- and polysaccharides with regular substitution patterns. Carbohydrate-binding modules (CBM) are non-catalytic protein domains that bind to polysaccharidic substrates. An important technical application involves their use as molecular probes to detect and localise specific carbohydrates in vivo. The three-dimensional structure of an evolved xyloglucan binding module (XGBM) was solved by X-ray diffraction. Affinity-guided directed evolution of this first generation XGBM resulted in highly specific probes that were used to localise non-fucosylated xyloglucans in plant tissue sections. / QC 20100902 enzyme engineering rational design directed evolution DNA shuffling glycosynthase xyloglucan xyloglucan endo-transglycosylase retaining glycoside hydrolase xyloglucanase carbohydrate binding module polysaccharide synthesis Bioengineering Bioteknik
6	Molecular and thermodynamic determinants of carbohydrate recognition by carbohydrate-binding modules and a bacterial pullulanase Lammerts van Bueren, Alicia 09 September 2008 (has links) Protein-carbohydrate interactions are pivotal to many biological processes, from plant cell wall degradation to host-pathogen interactions. Many of these processes require the deployment of carbohydrate-active enzymes in order to achieve their intended effects. One such class of enzymes, glycoside hydrolases, break down carbohydrate substrates by hydrolyzing the glycosidic bond within polysaccharides or between carbohydrates and non-carbohydrate moieties. The catalytic efficiency of glycoside hydrolases is often enhanced by carbohydrate-binding modules (CBMs) which are part of the modular structure of these enzymes. Understanding the carbohydrate binding function of these modules is often key to studying the catalytic properties of the enzyme. This thesis investigates the molecular determinants of carbohydrate recognition by CBMs that share similar amino acid sequences and overall three-dimensional structures and thus fall within the same CBM family. Specifically this research focused on two families; plant cell wall binding family 6 CBMs and the alpha-glucan binding family 41 CBMs. Through X-ray crystallography, isothermal titration calorimetry and other biochemical experiments, the structural and biophysical properties of CBMs were analyzed. Studying members of CBM family 6 allowed us to establish the overall picture of how similar CBMs interact with a diverse range of polysaccharide ligands. This was found to be due to changes in the topology of the binding site brought about by changes in amino acid side chains in very distinct regions of the binding pocket such that it adopted a three-dimensional shape that is complementary to the shape of the carbohydrate ligand. Members of CBM family 41 were shown to have nearly identical modes of starch recognition as found in starch-binding CBMs from other families. However family 41 CBMs are distinct as they are found mainly in pullulanases (starch debranching enzymes) and have developed binding pockets which are able to accommodate alpha-1,6-linkages, unlike other starch-binding CBM families. These are the first studies comparing multiple CBMs from within a given CBM family at the molecular level whose results allow us to examine the distinct modes of carbohydrate recognition within a CBM family. Analysis of the family 41 CBMs revealed that these CBMs are mainly found in pullulanases from pathogenic bacteria. Members from Streptococcal species were shown to specifically interact with glycogen stores within mouse lung tissue, leading us to investigate the role of alpha-glucan degradation by the pullulanase SpuA in the pathogenesis of Streptococcus pneumoniae. SpuA targets the alpha-1,6-branches in glycogen granules, forming alpha-1,4-glucan products of varying lengths. The overall three-dimensional structure of SpuA in complex with maltotetraose was determined by X-ray crystallography and showed that its active site architecture is optimal for interacting with branched substrates. Additionally, the N-terminal CBM41 module participates in binding substrate within the active site, a novel feature for CBMs. This is the first study of alpha-glucan degradation by a streptococcal virulence factor and aids in explaining why it is crucial for full virulence of the organism. X-Ray crystallography Protein-carbohydrate interaction carbohydrate-binding module Streptococcus pneumoniae glycoside hydrolase
7	Structural and functional studies on secreted glycoside hydrolases produced by clostridium perfringens Ficko-Blean, Elizabeth 21 April 2009 (has links) Clostridium perfringens is a gram positive spore forming anaerobe and a causative agent of gas gangrene, necrotic enteritis (pig-bel) and food poisoning in humans and other animals. This organism secretes a battery of exotoxins during the course of infection as well as a variety of virulence factors which may help to potentiate the activities of the toxins. Among these virulence factors is the μ-toxin, a family 84 glycoside hydrolase which acts to degrade hyaluronan, a component of human connective tissue. C. perfringens has 53 open reading frames encoding glycoside hydrolases. About half of these glycoside hydrolases are predicted to be secreted. Among these are CpGH84C, a paralogue of the μ-toxin, and CpGH89. CpGH89 shares sequence similarity to the human α-N-acetylglucosaminidase, NAGLU, in which mutations can cause a devastating genetic disease called mucopolysaccharidosis IIIB. One striking feature of the secreted glycoside hydrolase enzymes of C. perfringens is their modularity, with modules predicted to be dedicated to catalysis, carbohydrate-binding, protein-protein interactions and cell wall attachment. The extent of the modularity is remarkable, with some enzymes containing up to eight ancillary modules. In order to help understand the role of carbohydrate-active enzymes produced by bacterial pathogens, this thesis will focus on the structure and function of the modular extracellular glycoside hydrolase enzymes secreted by the disease causing bacterium, C. perfringens. These structure function studies examine two family 32 CBMs (carbohydrate-binding modules), one from the μ-toxin and the other from CpGH84C. As well we examine the complete structure of CpGH84C in order to help further our understanding of the structure of carbohydrate-active enzymes as a whole. Finally, the catalytic module of CpGH89 is characterized and its relationship to the human NAGLU enzyme is discussed. glycoside hydrolase GH84 carbohydrate binding module CBM32 Clostridium perfringens GH89 mucopolysaccharidosis IIIB Sanfilippo syndrome NAGLU modular enzymes
8	Kristallstrukturanalyse des kohlenhydratbindenden Moduls 27-1 der Beta-Mannanase 26 aus Caldicellulosiruptor saccharolyticus im Komplex mit Mannohexaose und Kristallisation der ATPase HP0525 aus Helicobacter pylori Roske, Yvette 28 July 2005 (has links) Kohlenhydrat-bindende Module (CBMs) sind die bekanntesten nicht-katalytischen Module, die mit Enzymen assoziiert sind, welche die pflanzliche Zellwand hydrolysieren. Die beta-Mannanase 26 von Caldicellulosiruptor saccharolyticus, Stamm Rt8B.4, ist eine thermostabile modulare Glycosidhydrolase, die N-terminal zwei dicht aufeinander folgende nicht-katalytische kohlenhydratbindende Module besitzt. Diese spezifisch beta-Mannan bindenden CBMs wurden kürzlich als Mitglieder der CBM-Familie 27 klassifiziert. Im ersten Teil dieser Arbeit wird die Kristallisation und Strukturanalyse des ersten kohlenhydratbindenden Moduls der ß-Mannanase aus C. saccharolyticus (CsCBM27-1) mit einer gebundenen Mannohexaose und in ligandfreier Form beschrieben. Grundlage für diese Arbeit waren Daten aus der isothermen Titrationskalorimetrie zur Quantifizierung der Affinität von CsCBM27-1 für lösliche Mannooligosaccharide. Die hier präsentierte hochaufgelöste Kristallstruktur des ungebundenen und Mannohexaose gebundenen CsCBM27-1 erlaubt weitere Einblicke in die Interaktion ß-Mannan bindender CBMs mit ihren entsprechenden Liganden. CsCBM27-1 zeigt eine typische ß-sandwich jellyroll-Struktur mit gebundenen Kalziumion. Die Mannohexaosebindung wird durch drei dem Lösungsmittel zugängliche Tryptophanreste und einige direkte Wasserstoffbrückenbindungen vermittelt. Der zweite Teil der Arbeit beschäftigt sich mit der Reinigung und Kristallisation der ATPase Virb11 HP0525 aus Helicobacter pylori. Das native Protein HP0525 ließ sich gut rekombinant herstellen und reinigen. Es wurde aus einer von mehreren Kristallisationsbedingungen durch Optimierung der Kristallisationskomponenten ausreichend große Kristalle erhalten, die gute Diffraktionseigenschaften zeigten. Neben dem nativen Protein wurde Selenomethionin-substituiertes Protein synthetisiert und gereinigt. Von diesem Protein SeMet-HP0525, resultierten hexagonale Kristalle. Zur Derivat-Datensatzsammlung ist es aufgrund der Publikation der Kristallstruktur dieser hexameren ATPase HP0525 nicht mehr gekommen. Weitere strukturelle Untersuchungen an diesem Protein wurden als nicht mehr erforderlich angesehen. / Carbohydrate-binding modules (CBMs) are the most common non-catalytic modules associated with enzymes active in plant cell-wall hydrolysis. Caldicellulosiruptor saccharolyticus strain Rt8B.4 Man26 is a thermostable modular glycoside hydrolase beta-mannanase which contains two non-catalytic modules in tandem at its N-terminus. These modules were recently shown to function primarily as ß-mannan-binding modules and have accordingly been classified as members of a novel family of CBMs, family 27. In the first part of this study, the crystallization and crystal structure analysis of the first carbohydrate binding module (CsCBM27-1) of the beta-mannanase from C. saccharolyticus in native and mannohexaose-bound form is described. The basis for this study were data from isothermal titration calorimetry for quantifying the binding affinity of CsCBM27-1 for soluble mannooligosaccharidesBoth structures permit further insights into the interaction of beta-mannan binding CBMs with their corresponding ligands. CsCBM27-1 shows the typical beta-sandwich jellyroll fold observed in other CBMs with a single calcium ion bound opposite to the ligand binding site. This arrangement is similar to topologies of other CBM families. The crystal structures reveal that the overall fold of CsCBM27-1 remains virtually unchanged upon sugar binding and that binding is mediated by three solvent-exposed tryptophan residues and few direct hydrogen bonds. The second part of this study addressed the purification and crystallization of the VirB11 ATPase HP0525 of Helicobacter pylori. The native HP0525 protein was produced in recombinant Escherichia coli and purified for crystallization. One of several crystallization experiments yielded large crystals by optimization of the concentration of the crystallization components. The crystals revealed good diffraction behavior. In addition to the native protein, selenomethionine-substituted HP0525 was produced and purified. Hexagonal crystals were obtained from the SeMet-HP0525. No derivative datasets were collected, because the crystal structure of the hexameric ATPase HP0525 was published by Yeo et al. (2000). Further structural investigations for the protein HP0525 were judged unnecessary. Kristallstruktur Kohlenhydrat-bindende Module Mannooligosaccharide Thermodynamik Superfamilie Carbohydrate-binding module Mannooligosaccharides Crystal structure Thermodynamics Superfamily 610 Medizin 33 Medizin UQ 5600 YC 5204 YC 5214 WD 5365 ddc:610

Search results