Global ETD Search

21	Strategies for cellulose fiber modification Persson, Per January 2004 (has links) This thesis describes strategies for and examples ofcellulose fiber modification.The ability of an engineered biocatalyst, acellulose-binding module fused to theCandida antarcticalipase B, to catalyze ring-openingpolymerization of e-caprolactone in close proximity tocellulose fiber surfaces was explored. The water content in thesystem was found to regulate the polymer molecular weight,whereas the temperature primarily influenced the reaction rate.The hydrophobicity of the cellulose sample increased as aresult of the presence of surface-deposited polyester. A two-step enzymatic method was also investigated. Here,Candida antarctica lipase B catalyzed the acylation ofxyloglucan oligosaccharides.The modified carbohydrates werethen incorporated into longer xyloglucan molecules through theaction of a xyloglucan endotransglycosylase. The modifiedxyloglucan chains were finally deposited on a cellulosesubstrate. The action ofCandida antarcticalipase B was further investigated inthe copolymerization of e-caprolactone and D,L-lactide.Copolymerizations with different e-caprolactone-to-D,L-lactideratios were carried out. Initially, the polymerization wasslowed by the presence of D,L-lactide. During this stage,D,L-lactide was consumed more rapidly than ε-caprolactoneand the incorporation occurred dimer-wise with regard to thelactic acid units. Morphological studies on wood fibers were conducted using asol-gel mineralization method. The replicas produced werestudied, without additional sample preparation, by electronmicroscopy and nitrogen adsorption. Information concerning thestructure and accessibility of the porous fiber wall wasobtained. Studies of never-dried kraft pulp casts revealedmicro-cavities and cellulose fibrils with mean widths of 4.7(±2) and 3.6 (±1) nm, respectively. Finally, cationic catalysis by simple carboxylic acids wasstudied. L-Lactic acid was shown to catalyze the ring-openingpolymerization of ε-caprolactone in bulk at 120 °C.The reaction was initiated with methylß-D-glucopyranoside, sucrose or raffinose, which resultedin carbohydrate-functionalized polyesters. The regioselectivityof the acylation was well in agreement with the correspondinglipase-catalyzed reaction. The polymerization was alsoinitiated with a hexahydroxy-functional compound, whichresulted in a dendrimer-like star polymer. The L-lactic acidwas readily recycled, which made consecutive reactions usingthe same catalyst possible. Keywords:Candida antarcticalipase B, cationic catalysis,cellulose-binding module, dendrimer, enzymatic polymerization,fiber modification, silica-cast replica, sol-gelmineralization, organocatalysis, xyloglucanendotransglycosylase Candida antarctica lipase B cationic catalysis cellulose-binding module dendrimer enzymatic polymerization fiber modification silica-cast replica sol-gel mineralization organocatalysis xyloglucan endotransglycosylase
22	Modélisation moléculaire de l'acétylation de la quercétine par des lipases : étude des interactions enzyme-substrat / Molecular Modeling of Quercetin Acetylation by Lipases : Study of Enzyme-Substrate Interactions Bidouil, Christelle 13 November 2012 (has links) La quercétine (QCT) est un composé polyphénolique d'origine végétale connu pour ses activités antioxydantes et ses effets bénéfiques sur la santé. Sa solubilité, sa stabilité, sa biodisponibilité et ses activités biologiques peuvent être améliorées par une acylation sélective de ses groupements hydroxylés. Ce travail vise à étudier la possibilité d'une acétylation enzymatique de la QCT par la lipase B de Candida antarctica (CALB), la lipase la plus exploitée industriellement pour des estérifications régio- et énantiosélectives. Dans une perspective d'ingénierie rationnelle de l'enzyme, une démarche de modélisation moléculaire est mise en oeuvre pour mieux comprendre les interactions qui régissent le positionnement et l'orientation du substrat dans le site actif de la lipase. Dans une première partie expérimentale, l'absence d'activité d'acétylation de la CALB envers la QCT, en présence d'un excès d'acétate de vinyle, a été confirmé. Dans une seconde partie, cette inactivité de la CALB a été expliquée à l'aide de simulations de docking et de dynamique moléculaire. Elle résulte d'une orientation inappropriée du donneur d'acyle liée à la sérine catalytique et d'une proximité insuffisante des hydroxyles de la QCT vis-à-vis des résidus catalytiques. L'éloignement de la QCT de la triade catalytique est due à la rigidité de la molécule, l'étroitesse du site actif ainsi qu'à des interactions hydrophobes et électrostatiques entre le substrat et les résidus de la cavité. En revanche, cette approche de simulation moléculaire prédit un bon positionnement des deux substrats dans le site actif de la lipase de Pseudomonas cepacia (PCL), laquelle est capable d'acétyler la QCT. Dans une troisième partie, l'influence de mutations de deux résidus impliqués dans les liaisons de stabilisation hydrophobe de la QCT dans la CALB a été investiguée par simulation. La substitution d'isoleucines par des valines et des alanines conduit à une augmentation du volume de la poche catalytique et une mobilité accrue de la QCT. Mais ces mutations sont insuffisantes pour permettre un positionnement adéquat de l'acétate et de la QCT par rapport à la triade catalytique. La dernière partie focalise sur les interactions électrostatiques entre la QCT et le site actif de CALB. Les orientations du substrat dans la cavité suite à une méthylation ou une acétylation des groupements hydroxyles de la QCT sont précisées / Quercetin (QCT) is a plant-produced polyphenolic compound well-known for its antioxidant activities and beneficial health effects. Its solubility, stability, bioavailability and biological activities may be improved by a selective acylation of its hydroxyl groups. This work aims at studying the possibility of QCT enzymatic acetylation by Candida antarctica lipase B (CALB), the most industrially exploited lipase for regio- and enantioselective esterifications. In prospect of the rational enzyme design, a molecular modeling approach was implemented to understand the interactions that govern the substrate positioning and orientation in the lipase's active site. In a first experimental part, the absence of CALB acetylation activity towards quercetin in excess of vinyl acetate was confirmed. In a second part, this inactivity of CALB was explained by means of docking and molecular dynamics simulations. This results from an inappropriate positioning of the acyl donor linked to the catalytic serine and from an insufficient proximity of QCT hydroxyls vis-à-vis catalytic residues. The distance of QCT from the catalytic triad is due to its rigidity and to the narrow active site as well as to hydrophobic and electrostatic interactions between the substrate and the cavity residues. On the contrary, this molecular simulation approach predicts an appropriate positioning of both substrates in the active site of Pseudomonas cepacia lipase (PCL), which can perform QCT acetylation. In a third part, the impact of mutations of two residues implicated in the stabilization of QCT by hydrophobic interactions in CALB was investigated through simulations. The substitution of isoleucines by alanines and valines led to an increase in the catalytic pocket volume which intensified the mobility of QCT. However, these mutations are insufficient to allow an appropriate positioning of acetate and QCT in relation to the catalytic triad. The last part of this work focuses on the electrostatic interactions between QCT and CALB's active site. The substrate orientation in the cavity following methylation or acetylation of QCT's hydroxyl groups was clarified Quercétine Lipase B de Candida antarctica Acétylation Modélisation moléculaire Docking Dynamique moléculaire Quercetin Candida antarctica Lipase B (CALB) Acetylation Molecular modeling Docking Molecular Dynamics 541.394
23	Rational redesign of Candida antarctica lipase B Magnusson, Anders January 2005 (has links) This thesis describes the use of rational redesign to modify the properties of the enzyme Candida antarctica lipase B. Through carefully selected single-point mutations, we were able to introduce substrate-assisted catalysis and to alter the reaction specificity. Other single-point mutations afforded variants with greatly changed substrate selectivity and enantioselectivity. Mutation of the catalytic serine changed the hydrolase activity into an aldolase activity. The mutation decreased the activation energy for aldol addition by 4 kJ×mol-1, while the activation energy increased so much for hydrolysis that no hydrolysis activity could be detected. This mutant can catalyze aldol additions that no natural aldolases can catalyze. Mutation of the threonine in the oxyanion hole proved the great importance of its hydroxyl group in the transition-state stabilization. The lost transition-state stabilization was partly replaced through substrate-assisted catalysis with substrates carrying a hydroxyl group. The poor selectivity of the wild-type lipase for ethyl 2-hydroxypropanoate (E=1.6) was greatly improved in the mutant (E=22), since only one enantiomer could perform substrate-assisted catalysis. The redesign of the size of the stereospecificity pocket was very successful. Mutation of the tryptophan at the bottom of this pocket removed steric interactions with secondary alcohols that have to position a substituent larger than an ethyl in this pocket. This mutation increased the activity 5 500 times towards 5-nonanol and 130 000 times towards (S)-1-phenylethanol. The acceptance of such large substituents (butyl and phenyl) in the redesigned stereospecificity pocket increases the utility of lipases in biocatalysis. The improved activity with (S)-1-phenylethanol strongly contributed to the 8 300 000 times change in enantioselectivity towards 1-phenylethanol; example of such a large change was not found in the literature. The S-selectivity of the mutant is unique for lipases. Its enantioselectivity increases strongly with temperature reaching a useful S-selectivity (E=44) at 69 °C. Thermodynamics analysis of the enantioselectivity showed that the mutation in the stereospecificity pocket mainly changed the entropic term, while the enthalpic term was only slightly affected. This pinpoints the importance of entropy in enzyme catalysis and entropy should not be neglected in rational redesign. Biochemistry Candida antarctica lipase B rational redesign secondary alcohols substrate-assisted catalysis S-selective entropy aldolase stereospecificity pocket oxyanion hole. Biokemi Biochemistry Biokemi
24	Strategies for cellulose fiber modification Persson, Per January 2004 (has links) <p>This thesis describes strategies for and examples ofcellulose fiber modification.The ability of an engineered biocatalyst, acellulose-binding module fused to the<i>Candida antarctica</i>lipase B, to catalyze ring-openingpolymerization of e-caprolactone in close proximity tocellulose fiber surfaces was explored. The water content in thesystem was found to regulate the polymer molecular weight,whereas the temperature primarily influenced the reaction rate.The hydrophobicity of the cellulose sample increased as aresult of the presence of surface-deposited polyester.</p><p>A two-step enzymatic method was also investigated. Here,Candida antarctica lipase B catalyzed the acylation ofxyloglucan oligosaccharides.The modified carbohydrates werethen incorporated into longer xyloglucan molecules through theaction of a xyloglucan endotransglycosylase. The modifiedxyloglucan chains were finally deposited on a cellulosesubstrate.</p><p>The action of<i>Candida antarctica</i>lipase B was further investigated inthe copolymerization of e-caprolactone and D,L-lactide.Copolymerizations with different e-caprolactone-to-D,L-lactideratios were carried out. Initially, the polymerization wasslowed by the presence of D,L-lactide. During this stage,D,L-lactide was consumed more rapidly than ε-caprolactoneand the incorporation occurred dimer-wise with regard to thelactic acid units.</p><p>Morphological studies on wood fibers were conducted using asol-gel mineralization method. The replicas produced werestudied, without additional sample preparation, by electronmicroscopy and nitrogen adsorption. Information concerning thestructure and accessibility of the porous fiber wall wasobtained. Studies of never-dried kraft pulp casts revealedmicro-cavities and cellulose fibrils with mean widths of 4.7(±2) and 3.6 (±1) nm, respectively.</p><p>Finally, cationic catalysis by simple carboxylic acids wasstudied. L-Lactic acid was shown to catalyze the ring-openingpolymerization of ε-caprolactone in bulk at 120 °C.The reaction was initiated with methylß-D-glucopyranoside, sucrose or raffinose, which resultedin carbohydrate-functionalized polyesters. The regioselectivityof the acylation was well in agreement with the correspondinglipase-catalyzed reaction. The polymerization was alsoinitiated with a hexahydroxy-functional compound, whichresulted in a dendrimer-like star polymer. The L-lactic acidwas readily recycled, which made consecutive reactions usingthe same catalyst possible.</p><p><b>Keywords:</b><i>Candida antarctica</i>lipase B, cationic catalysis,cellulose-binding module, dendrimer, enzymatic polymerization,fiber modification, silica-cast replica, sol-gelmineralization, organocatalysis, xyloglucanendotransglycosylase</p> Candida antarctica lipase B cationic catalysis cellulose-binding module dendrimer enzymatic polymerization fiber modification silica-cast replica sol-gel mineralization organocatalysis xyloglucan endotransglycosylase
25	Étude de la sélectivité d'acylation enzymatique de peptides : prédiction de la sélectivité de la lipase B de Candida antarctica par modélisation moléculaire et recherche de nouvelles enzymes spécifiques de type aminoacylases / Study of the enzymatic selectivity for peptides acylation : prediction of the selectivity of the Candida antarctica lipase B through molecular modeling approach and research of new specific aminoacylases enzymes Ferrari, Florent 10 October 2014 (has links) Les peptides sont des molécules pouvant posséder une activité biologique intéressante (antibiotique, anti-oxydante, antivirale, anti-hypertensive…). Ce sont cependant des molécules difficiles à utiliser car elles possèdent un faible temps de demi-vie in vivo et sont peu bio-disponibles. Le greffage d’un acide gras permet de les protéger et d’accroître leur potentiel d’action. Cette réaction appelée acylation peut être catalysée par des enzymes. A l’heure actuelle, peu de recherches sont faites sur l’acylation de peptides par voie enzymatique et sur la recherche de nouveaux biocatalyseurs adaptés pour cette réaction. Les objectifs de cette thèse ont été, dans un premier temps, de comprendre les mécanismes de la sélectivité d’acylation de peptides de la lipase B de Candida antarctica par une approche de modélisation moléculaire combinant docking et dynamique moléculaire, couplée à une approche expérimentale. Cette étude a permis d’identifier des interactions enzyme-substrats impliquées dans la sélectivité enzymatique et a permis de construire un modèle expliquant la régio- et chimio-sélectivité de l’acylation peptidique catalysée par cette enzyme. Dans un deuxième temps, une étude préliminaire a été menée afin d’identifier de nouvelles enzymes de type acylases présentes dans des surnageants de culture de différentes espèces de Streptomyces. Ces enzymes sont capables de catalyser des réactions d’acylation de peptides en milieux aqueux. Une méthode de semi-purification a été établie et une étude comparative a été menée sur la sélectivité d’acylation de la lipase B de C. antarctica et celle de nouvelles enzymes de type aminoacylases présentes dans un extrait protéique de surnageant de culture de Streptomyces ambofaciens. Ces nouvelles enzymes présentent une spécificité différente de celle de la lipase B de C. antarctica, permettant notamment, une acylation des acides aminés sur leur fonction amine en position α. Une caractérisation partielle des activités amino-acylase du surnageant de culture de S. ambofaciens a été réalisée. Dans une troisième et dernière partie, une comparaison des séquences génétiques a été réalisée entre treptomyces mobaraensis et S. ambofaciens afin d’identifier les gènes codant pour les acylases découvertes chez S. ambofaciens. Des mutants de S. ambofaciens délétés pour ces gènes ont été construits et la fonctionnalité des enzymes codées par ces gènes a été vérifiée ; enfin, une expression hétérologue de l’ε-lysine acylase a été initiée / Peptides exhibit various beneficial effects such as antioxidant, anti-hypertensive, neuroprotective, antiviral or antimicrobial activities. However, their use can be limited by their short half-life and their low biological availability. One solution to overcome these drawbacks is the acylation of peptides with fatty acids. This reaction called acylation can be catalyzed using enzymes. To date, very few studies focus on enzymatic acylation of peptides and on finding new enzymes catalyzing this reaction. The objectives of this work were, in a first time, to understand the selectivity mechanisms of the lipase B of Candida antarctica for peptides acylation combining experimental and molecular modeling approaches. This study highlighted enzyme/substrate interactions involved in the enzymatic selectivity and a modelexplaining the chemo- and regio-selectivity of this enzyme for peptide acylation reactions was built. In a second time, a preliminary study was carried out in order to identify new aminoacylase enzymes produced in the culture supernatant of various species of Streptomyces. These enzymes are able to catalyze acylation of peptides in aqueous media. A partial purification method was set and a comparative study was performed on the selectivity of C. antarctica lipase Band that of the new aminoacylases discovered in the culture supernatant of Streptomyces ambofaciens ATCC 23877. These enzymes presented a selectivity different from C. antarctica lipase B allowing the acylation of the N-terminal amino group of amino acids or peptides. A partial description of the aminoacylase activity of the supernatant crude extract of S. ambofaciens was performed. In a third and final part, a comparison of sequences of aminoacylases from Streptomyces mobaraensis with the genome of S.s ambofaciens ATCC 23877 was performed in order to identify genetic sequences encoding the new discovered aminoacylases from S. ambofaciens ATCC 23877. Each identified gene was deleted to correlate it with the aminoacylase activity observed in the crude extract of S. ambofaciens. Lastly, a heterologous expression of the ε-lysine acylase was initiated Sélectivité enzymatique Acylation peptidique Lipase B de Candida antarctica Acylases Modélisation moléculaire Expression hétérologue Enzymatic selectivity Peptide acylation Candida antarctica lipase B Acylases Molecular modeling Heterologous expression 660.634
26	Lipase chemoselectivity - kinetics and applications Hedfors, Cecilia January 2009 (has links) A chemoselective catalyst is preferred in a chemical reaction where protecting groups otherwise are needed. The two lipases Candida antarctica lipase B and Rhizomucor miehei lipase showed large chemoselectivity ratios, defined as (kcat/KM)OH / (kcat/KM)SH, in a transacylation reaction with ethyl octanoate as acyl donor and hexanol or hexanethiol as acyl acceptor (paper I). The chemoselectivity ratio of the uncatalyzed reaction was 120 in favour of the alcohol. Compared to the uncatalyzed reaction, the chemoselectivity was 730 times higher for Candida antarctica lipase B and ten times higher for Rhizomucor miehei lipase. The KM towards the thiol was more than two orders of magnitude higher than the KM towards the corresponding alcohol. This was the dominating contribution to the high chemoselectivity displayed by the two lipases. In a novel approach, Candida antarctica lipase B was used as catalyst for enzymatic synthesis of thiol-functionalized polyesters in a one-pot reaction without using protecting groups (paper II). Poly(e-caprolactone) with a free thiol at one of the ends was synthesized in an enzymatic ring-opening polymerization initiated with mercaptoethanol or terminated with either 3-mercaptopropionic acid or g-thiobutyrolactone. Candida antarctica lipase B Rhizomucor miehei lipase active site titration kinetics chemoselectivity thiol alcohol thiol-functionalized polyesters Biochemistry and Molecular Biology Biokemi och molekylärbiologi
27	Modélisation moléculaire et expérimentation en réacteur solide/gaz pour la compréhension de la sélectivité de la lipase B de Candida antarctica / Molecular modeling and experimentation in solid/gas reactor for understanding the selectivity of lipase B from Candida antarctica Marton, Zsuzsanna 22 July 2010 (has links) L’objectif de cette thèse était de mieux comprendre les paramètres structuraux et environnementaux gouvernant l’énantiosélectivité de la lipase B de Candida antarctica (CALB), lors de la résolution des alcools secondaires linéaires chiraux. Ces composés sont notamment utilisés comme synthons chiraux dans l’industrie pharmaceutique. Dans un premier temps, une étude systématique des orientations du butan-2-ol et du pentan-2-ol au sein du site actif a été réalisée par modélisation moléculaire. Les résultats suggèrent l’existence de modes d’arrimages supplémentaires à ceux mentionnés dans la littérature. La comparaison selon l’énergie potentielle du substrat des structures les plus stables, combinée à la prise en compte de modes de fixation non productifs, nous a permis d’expliquer qualitativement l’énantiopréférence de la CALB pour la forme R. A l’aide du réacteur solide/gaz, nous avons montré que les résidus hydrophobes formant le canal d’accès du substrat au site actif (Ile189, Leu278 et Ala282), jouaient un rôle significatif dans l’énantiosélectivité de la CALB vis-à-vis des alcools secondaires. L’influence de la partie alkoxy du donneur d’acyle sur le ratio énantiomérique a également pu être mise en évidence. Par ailleurs, nous avons montré que des mutations isostériques de la poche stéréosélective conduisaient à des variations des paramètres thermodynamiques d’activation de l’acylation du pentan-2-ol, probablement suite à des modifications du réseau de liaisons hydrogène formé entre les résidus de la poche. Les études d’adsorption de l'eau et des substrats sur l’enzyme immobilisée nous ont permis de relier l'état d'hydratation de la CALB avec les effets particuliers de l'eau sur l’activité et la sélectivité de l’enzyme. / The aim of this thesis was to understand more precisely the structural and environmental parameters governing the enantioselectivity of lipase B from Candida antarctica (CALB), involved in the discrimination of chiral secondary alcohols enantiomers. These compounds are used in particular for the synthesis of enantiomerically pure pharmaceutical molecules. Initially a systematic study of the orientation of butan-2-ol and pentan-2-ol in the active site was performed by molecular modeling. The results suggest the existence of additional binding modes to those mentioned in the literature. The potential energy comparison of the most stable conformations of the substrate, combined with the existence of non productive binding modes, allowed us to explain qualitatively the enantiopreference of CALB for the R form. Using the solid/gas reactor, we have shown that hydrophobic residues forming the access channel of substrate to the active site (Ile189, Leu278 and Ala282), played a significant role in the enantioselectivity of CALB towards secondary alcohols. The influence of the alkoxy part of the acyl donor on the enatiomeric ratio E has also been highlighted. Furthermore, we showed that isosteric mutations of the stereoselective pocket led to changes in pentan-2-ol activation thermodynamic parameters of acylation, probably due to changes in the hydrogen bonds network formed between residues of the pocket. Studies of water and substrates adsorption on the immobilized enzyme allowed us to relate the hydration status of CALB with specific effects of water on the enzyme activity and selectivity. Lipase B de Candida antarctica Énantiosélectivité Réacteur solide/gaz Modélisation moléculaire Chromatographie gazeuse en phase inverse Alcoolyse Activité thermodynamique Candida antarctica lipase B Enantioselectivity Solid/gas reactor Molecular modeling Inverse gas chromatography Alcoholysis Thermodynamic activity
28	Functionalization and Synthesis of Difunctional Folate-targeted Polymeric Conjugates for Potential Diagnostic Applications Shrikhande, Gayatri January 2019 (has links) No description available. Chemistry Chemical Engineering Materials Science Polymer Chemistry Polymers Biomedical Engineering Enzyme catalysis Candida antarctica lipase B Transesterification Michael addition Fluorescein functionalization Polyethylene glycol Tetraethylene glycol Folic acid Acrylation PEGylation Lithiation Kinetic study Diagnostic Scale-up Polymeric conjugates
29	Synthesis of Folate-Targeted Poly(Ethylene Glycol)-Based Conjugates And Their Precursors Mulay, Prajakatta January 2019 (has links) No description available. Chemical Engineering Chemistry Molecules Organic Chemistry Polymer Chemistry Polymers poly ethylene glycol Candida antarctica Lipase B polymer functionalization enzyme catalysis gamma conjugated folic acid PEG thiol PEG amine PEG bromide folate targeted conjugates transesterification Michael addition Sefose cyclic polydisulfide

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