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Asymmetric transformation of ß- and γ-functionalized alcohols : Study of combined ruthenium-catalyzed racemization and enzymatic resolutionTräff, Annika January 2011 (has links)
The major part of this thesis describes the asymmetric synthesis of β- and γ-amino alcohols through the combination of ruthenium catalyzed racemization and enzymatic kinetic resolution. The dynamic kinetic resolution, DKR, protocol for chlorohydrins was improved by employing Bäckvall’s catalyst, which is a base activated racemization catalyst, in combination with Burkholderia cepacia lipase. These optimized conditions broadened the substrate scope and improved the yields and ee’s of the obtained chlorohydrin acetates. The utility of the method was demonstrated in the synthesis of (S)-salbutamol. In the second part of the thesis, DKR was utilized in the enantio-determining step of the total synthesis of (R)-duloxetine. Optimized DKR conditions, combining Bäckvall’s catalyst together with Candida antarctica lipase B, afforded a β-cyano acetate in high yield and ee. (R)-Duloxetine was accessible through synthetic alterations of the enantioenriched β-cyano acetate in high overall yield. A dynamic kinetic asymmetric transformation, DYKAT, protocol to obtain enantio- and diastereomerically pure γ-amino alcohols was developed. In a first step N-Boc-aminoketones were obtained in high enantiomeric purity through a proline-catalyzed Mannich reaction. Subsequent in situ reduction coupled with a highly efficient DYKAT yielded γ-amino acetates in high dr and ee. The γ-amino alcohols were available through simple hydrolysis/deprotection with retained stereochemistry. In the final part of the thesis a heterogeneous bifunctional catalytic system is reported, which combines the catalytic properties of transition metal-catalyzed racemization with enzymatic acylation. A novel ruthenium-phosphonate complex was synthesized and then covalently anchored to the active site of solid supported Candida antarctica lipase B. The partially inhibited beads proved to be catalytically active both in racemization as well as enzymatic acylation. / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: In press. Paper 3: Epub ahead of print.
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Functionalization and Synthesis of Difunctional Folate-targeted Polymeric Conjugates for Potential Diagnostic ApplicationsShrikhande, Gayatri January 2019 (has links)
No description available.
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Synthesis of Folate-Targeted Poly(Ethylene Glycol)-Based Conjugates And Their PrecursorsMulay, Prajakatta January 2019 (has links)
No description available.
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Green Polymer Chemistry: Synthesis of Poly(disulfide) Polymers and NetworksRosenthal-Kim, Emily Quinn January 2013 (has links)
No description available.
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Mutagénèse semi-aléatoire au site actif de la DHFR humaine : création et caractérisation de variantes hautement résistantes au MTX.Volpato, Jordan 12 1900 (has links)
La dihydrofolate réductase humaine (DHFRh) est une enzyme essentielle à la prolifération cellulaire. Elle réduit le dihydrofolate en tétrahydrofolate, un co-facteur impliqué dans la biosynthèse des purines et du thymidylate. La DHFRh est une cible de choix pour des agents de chimiothérapie comme le méthotrexate (MTX), inhibant spécifiquement l’enzyme ce qui mène à un arrêt de la prolifération et ultimement à la mort cellulaire. Le MTX est utilisé pour le traitement de plusieurs maladies prolifératives, incluant le cancer. La grande utilisation du MTX dans le milieu clinique a mené au développement de mécanismes de résistance, qui réduisent l’efficacité de traitement. La présente étude se penche sur l’un des mécanismes de résistance, soit des mutations dans la DHFRh qui réduisent son affinité pour le MTX, dans le but de mieux comprendre les éléments moléculaires requis pour la reconnaissance de l’inhibiteur au site actif de l’enzyme. En parallèle, nous visons à identifier des variantes plus résistantes au MTX pour leur utilisation en tant que marqueurs de sélection en culture cellulaire pour des systèmes particuliers, tel que la culture de cellules hématopoïétiques souches (CHS), qui offrent des possibilités intéressantes dans le domaine de la thérapie cellulaire.
Pour étudier le rôle des différentes régions du site actif, et pour vérifier la présence d’une corrélation entre des mutations à ces régions et une augmentation de la résistance au MTX, une stratégie combinatoire a été dévelopée pour la création de plusieurs banques de variantes à des résidus du site actif à proximité du MTX lié. Les banques ont été sélectionnées in vivo dans un système bactérien en utilisant des milieux de croissance contenant des hautes concentrations de MTX. La banque DHFRh 31/34/35 généra un nombre considérable de variantes combinatoires de la DHFRh hautement résistantes au MTX. Les variantes les plus intéressantes ont été testées pour leur potentiel en tant que marqueur de sélection dans plusieurs lignées cellulaires, dont les cellules hématopoïétiques transduites. Une protection complète contre les effets cytotoxiques du MTX a été observée chez ces cellules suite à leur infection avec les variantes combinatoires. Pour mieux comprendre les causes moléculaires reliées à la résistance au MTX, des études de structure tridimensionnelle de variantes liées au MTX ont été entreprises. La résolution de la structure de la double variante F31R/Q35E lié au MTX a révélé que le phénotype de résistance était attribuable à d’importantes différences entre le site actif de la double variante et de l’enzyme native, possiblement dû à un phénomème dynamique. Une compréhension plus générale de la reconnaissance et la résistance aux antifolates a été réalisée en comparant des séquences et des structures de variantes de la DHFR résistants aux antifolates et provenant de différentes espèces.
En somme, ces travaux apportent de nouveaux éléments pour la comprehension des intéractions importantes entre une enzyme et un ligand, pouvant aider au développement de nouveaux antifolates plus efficaces pour le traitement de diverses maladies. De plus, ces travaux ont généré de nouveaux gènes de résistance pouvant être utilisés en tant que marqueurs de sélection en biologie cellulaire. / Human dihydrofolate reductase (hDHFR) is an enzyme that is essential to cell proliferation. It reduces dihydrofolate to tetrahydrofolate, an important cofactor involved in purine and thymidylate biosynthesis. hDHFR is a choice target for chemotherapeutic drugs like methotrexate (MTX), which specifically inhibits the enzyme, stopping cell proliferation and leading to cellular death. MTX is used for the treatment of many proliferative diseases, including cancers. Widespread use of MTX has lead to the development of resistance mechanisms appear which impair treatment efficiency. The present work focuses on a mechanism of resistance, namely mutations in hDHFR that reduce its affinity for MTX, to better understand the underlying mechanisms of inhibitor recognition at the active site of the enzyme. In parallel, we aim at identifying the most MTX-resistant variants to offer novel selectable markers for particular cell culture systems, such as hematopoietic cell culture, which offer important perspectives for cellular therapy.
To study the role of different regions of the hDHFR active site, and to verify if a correlation exists between mutations in these regions and increased resistance to MTX, a combinatorial strategy was developed enabling the creation of several hDHFR variant libraries at active site residues located in proximity to bound MTX. The libraries were selected in vivo in a bacterial system using culture media containing high concentration of the inhibitor. One library in particular, hDHFR 31/34/35, yielded a considerable number of highly MTX-resistant combinatorial hDHFR variants. The most interesting candidates were tested for their potential as selectable markers in various cell lines, including transduced hematopoietic cells. Complete protection from MTX-cytotoxicity was obtained for these cells following infection with the combinatorial variants. To better understand the molecular causes of MTX resistance, resolution of the crystal structures of variant proteins in presence of MTX was attempted. Resolution of the F31R/Q35E double variant revealed that the resistance phenotype was related to important differences in the active site relative to WT, possibly attributable to a dynamic motion effect. A more general comprehension of antifolate recognition and resistance was achieved by sequence and structural comparison of antifolate-resistant DHFR variants from different species.
Overall, our work contributes to the better understanding of enzyme-inhibitor interactions, which could provide new insights into the development of more efficient clinical therapies. In addition, this work has yielded novel drug-resistance genes useful as selectable markers for cellular biology.
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Mutagénèse semi-aléatoire au site actif de la DHFR humaine : création et caractérisation de variantes hautement résistantes au MTXVolpato, Jordan 12 1900 (has links)
No description available.
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Structure-function studies of the oxidoreductase bilirubin oxidase from Myrothecium verrucaria using an electrochemical quartz crystal microbalance with dissipationSingh, Kulveer January 2014 (has links)
This thesis presents the development and redesign of a commercial electrochemical quartz crystal microbalance with dissipation (E–QCM–D). This was used to study factors affecting the efficiency of the four electron reduction catalysed by the fuel cell enzyme bilirubin oxidase from Myrothecium verrucaria immobilised on thiol modified gold surfaces. Within this thesis, the E–QCM–D was used to show that application of a constant potential to bilirubin oxidase adsorbed to thiol-modified gold surfaces causes activity loss that can be attributed to a change in structural arrangement. Varying the load by potential cycling distorts the enzyme by inducing rapid mass loss and denaturation. Attaching the enzyme covalently reduces the mass loss caused by potential cycling but does not mitigate activity loss. Covalent attachment also changes the orientation of the surface bound enzyme as verified by the position of the catalytic wave (related to the overpotential for catalysis) and reactive labelling followed by mass spectrometry analysis. The E–QCM–D was used to show how electrostatic interactions affect enzyme conformation where high pH causes a reduction in both mass loading at the electrode and a reduction in activity. At pH lower than the enzyme isoelectric point, there is a build up of multilayers in a clustered adsorption. When enzyme adsorbs to hydrophobic surfaces there is a rapid denaturation which completely inactivates the enzyme. Changing the surface chemistry from carboxyl groups to hydroxyl and acetamido groups shows that catalysis is shifted to more negative potentials as a result of an enzyme misorientation. Further to this, increasing the chain length of the thiol modifier indicates that an increased distance between surface and enzyme reduces activity, enzyme loading and results in a conformational rearrangement that permits electron transfer over longer distances.
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