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From Probes to Cell Surface Labelling: Towards the Development of New Chemical Biology Compounds and MethodsLegault, Marc 29 June 2011 (has links)
Chemical biology encompasses the study and manipulation of biological system using chemistry, often by virtue of small molecules or unnatural amino acids. Much insight has been gained into the mechanisms of biological processes with regards to protein structure and function, metabolic processes and changes between healthy and diseased states. As an ever expanding field, developing new tools to interact with and impact biological systems is an extremely valuable goal. Herein, work is described towards the synthesis of a small library of heterocyclic-containing small molecules and the mechanistic details regarding the interesting and unexpected chemical compounds that arose; an alternative set of non-toxic copper catalyzed azide-alkyne click conditions for in vivo metabolic labelling; and the synthesis of an unnatural amino acid for further chemical modification via [3+2] cycloadditions with nitrones upon incorporation into a peptide of interest. Altogether, these projects strive to supplement pre-existing methodology for the synthesis of small molecule libraries and tools for metabolic labelling, and thus provide further small molecules for understanding biological systems.
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From Probes to Cell Surface Labelling: Towards the Development of New Chemical Biology Compounds and MethodsLegault, Marc 29 June 2011 (has links)
Chemical biology encompasses the study and manipulation of biological system using chemistry, often by virtue of small molecules or unnatural amino acids. Much insight has been gained into the mechanisms of biological processes with regards to protein structure and function, metabolic processes and changes between healthy and diseased states. As an ever expanding field, developing new tools to interact with and impact biological systems is an extremely valuable goal. Herein, work is described towards the synthesis of a small library of heterocyclic-containing small molecules and the mechanistic details regarding the interesting and unexpected chemical compounds that arose; an alternative set of non-toxic copper catalyzed azide-alkyne click conditions for in vivo metabolic labelling; and the synthesis of an unnatural amino acid for further chemical modification via [3+2] cycloadditions with nitrones upon incorporation into a peptide of interest. Altogether, these projects strive to supplement pre-existing methodology for the synthesis of small molecule libraries and tools for metabolic labelling, and thus provide further small molecules for understanding biological systems.
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Entwicklung von funktionellen Polymerbürsten mit modularen EigenschaftenRauch, Sebastian 30 July 2013 (has links) (PDF)
Im Rahmen dieser Arbeit wurden neuartige, temperatursensitive Polymerbürsten mit terminaler Click-Funktionalität hergestellt, die nicht nur im Detail untersucht bzw. charakterisiert wurden, sondern deren Eigenschaften zusätzlich durch die polymeranaloge Umsetzung mit einem entsprechend modifizierten Fluoreszenzfarbstoff, Polymer oder mit superparamagnetischen Nanopartikeln erweitert werden konnten. Mittels kontrolliert radikalischer Polymerisation wurde mono- und bi-funktionalisiertes Poly(N-isopropylacrylamid) mit unterschiedlichen Endgruppen und Molekulargewichten synthetisiert und über das "grafting to"-Verfahren an eine Modeloberfläche angebunden. Die kovalente Anbindung der entsprechenden Komponenten erfolgte entweder durch die Kupfer-katalysierte oder thermisch induzierte Alkin-Azid-Cycloaddition. Neben den physiko-chemischen Eigenschaften wurde im Besonderen das temperaturabhängige Schaltverhalten dieser funktionellen Polymerbürsten in situ untersucht, wobei neben der spektroskopischen Ellipsometrie als Hauptmethode, zusätzlich Rasterkraftmikroskopie, UV/VIS- und Fluoreszenzspektroskopie, sowie Elektronenmikroskopie verwendet wurden. Im Fall der Farbstoff-modifizierten Polymerbürsten zeigte sich, dass nicht nur die Eigenschaften des Farbstoffs durch das Polymer beeinflussbar sind, sondern auch das Quellverhalten der Polymerbürsten durch den Farbstoff. Die mit Nanopartikeln modifizierten Polymerbürsten zeigten eine homogene Verteilung der Partikel auf der Oberfläche, sowie eine veränderte Schaltcharakteristik, die durch das Auftreten eine dynamischen Wechselwirkungszone zwischen den Polymerbürsten und den Nanopartikeln erklärt werden kann. Mit Hilfe der thermisch induzierten Azid-Alkin-Cycloaddition konnten erstmalig definierte Kettenverlängerungen an Polymerbürsten durchgeführt und gleichzeitig der Nachteil der limitierten Pfropfungsdichte der „grafting to“-Methode überwunden werden. Darüber hinaus konnte der temperaturinduzierte Schalteffekt nicht nur erhalten bleiben, sondern in Bezug auf die Schaltamplitude auch signifikant vergrößert werden und ergab ein sensitiveres, verbessertes Polymerbürstensystem.
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Functional polymer layers with protected aminesSieczkowska, Barbara 13 June 2009 (has links) (PDF)
This work refers to the area of bio-nanotechnology and concerns the selective immobilization of DNA or other bio-template on microstructured gold contacts and which then permit a coordinated cooperation of several of these nanotemplate, e.g., within a microreactor. The immobilization of such nano-objects should be realized through functional thin polymer films which provide binding groups. Thus, the main aim of this work was the development of polymeric materials for thin functional films which permit to deposit on different substrates a wide variation of functional elements or metal structures and to achieve a pattern formation using optical grid methods. In order to realize this concept it was necessary to design and develop a polymer system based on suitable photolabile units and in addition having anchoring groups which attach on specific substrates like gold. In this terpolymer concept was aimed for which consists of three components with particular functions in suitable molar ratios, which allow the tune the properties of the materials, and provide: amino photolabile protected groups for the photolithographic creation of patterned areas with free amino groups, which are available for further modifications like attachment of colloids, metallization or attachment of DNA strands; disulfide derivative anchor groups providing anchoring capacity for gold surface and spacer groups for adjusting the film quality. These multifunctional terpolymers should be synthesised by free radical polymerisation of suitable monomers. Although these techniques are successful, they are limited by their complexity, rigorous synthetic demands, as well as incompatibility with many functional termolabile and highly reactive functionalities. To overcome these difficulties a polymerisation technique based on “living” free radical polymerisation has been used in this work. A highly efficient polymer-analogous modification allows to introduce the functionalities after the polymer construction reaction. The production of suitable prepolymers [poly(styrene-r-4-propargyl-oxystyrene)] was carried out with the help of a controlled synthesis methodology “nitroxide mediate radical polymerization" followed by polymer analogous reaction using one of the most efficient click reactions, the Cu(I) catalyzed Huisgen 1,3-dipolar cycloaddition between terminal acetylenes and azides to attach further functionalities through the formation of a stable 1,4-disubstituted 1,2,3-triazol ring . The combination of nitroxide mediated radical polymerization (NMRP) and click chemistry was used to produce well-defined random copolymer. It could already be shown that also block copolymers can be prepared which give the chance to combine nanostructure formation in block copolymers with special functionality. Thus, the special properties of these functional polymers like the capability for photopatterning and anchoring onto gold substrates make them very interesting for nanotechnology applications. / Diese Arbeit bezieht sich auf das Gebiet der Bionanotechnologie und betrifft ein neuartiges Verfahren zur selektiven Immobilisierung der DNA oder anderer Biomoleküle auf mikrostrukturierten Goldkontakten, welche dann ein koordiniertes Zusammenwirken von einzelnen Nanomolekülen ermöglichen, z.B. in einem Mikroreaktor. Die Immobilisierung solcher Nanoobjekte soll durch dünne Funktionsschichten realisiert werden, die die Anbindungsgruppen liefern. Folglich war das Hauptziel dieser Arbeit die Entwicklung von Polymermaterialien für dünne Funktionsschichten, die die Aufbringung einer großen Vielzahl von Funktionselementen oder metallischen Strukturen auf verschiedenen Substraten gestatten und die Strukturierung durch den Einsatz von lithographischen Methoden ermöglichen. Um dieses Konzept zu realisieren, war es notwendig, ein Polymersystem zu gestalten und zu entwickeln, welches auf geeignete photolabile Einheiten basiert und zusätzlich Ankergruppen hat, die mit spezifischen Substraten wie Gold verbunden ist. Dieses Terpolymerkonzept wurde gezielt aus drei Komponenten mit speziellen Funktionen in entsprechenden molaren Verhältnissen gebildet, die eine Abstimmung der Materialeigenschaften ermöglicht und folgendes bereitstellt: photolabile geschützte Aminogruppen für die photolitographische Strukturerzeugung mit freien Aminogruppen, welche für weitere Modifikationen verfügbar sind wie das Anhängen von Kolloiden, die Metallisierung oder Anfügung von DNA-Strängen; disulfide Derivate für die kovalente Anbindung auf der Goldoberfläche und Spacer-Gruppe für Verbesserung der Schichtenbildung. Diese multifunktionalen Terpolymere sollen durch eine freie radikalische Polymerisation von entsprechenden Monomeren synthetisiert werden. Obwohl diese Techniken erfolgreich sind, sind sie eingeschränkt durch ihre Komplexität, den strengen synthetischen Anforderungen, sowie der Inkompatibilität mit vielen funktionalen thermolabilen und hochreaktiven Funktionalitäten. Um diese Schwierigkeiten zu überwinden wurde eine Polymerisationstechnik für diese Arbeit genutzt, die auf der „lebenden“ freien radikalischen Polymerisation basiert. Eine hoch effiziente polymeranaloge Modifizierung erlaubt die Einführung von Funktionalitäten nach der Polymeraufbaureaktion. Die Herstellung von entsprechenden Präpolymeren Poly(Styrol-r-4-Propargyl-oxystyrol) wurde mittels einer kontrollierten Synthesemethodik „Nitroxid-mediated controled radical polymerisation“ (NMRP) durchgeführt, gefolgt von der Polymeranalogreaktion, die eine der effizientesten Click-Reaktion - die Cu(I) katalysierte 1,3-dipolar Cycloaddition von terminalen Alkinen an Aziden nach Huisgen nutzt, um weiter Funktionalitäten durch die Bildung eines stabilen 1,4-disubstituierten-[1,2,3]-Triazolringes anzufügen. Die Kombination von NMRP und Click-Chemie wurde zur Herstellung eines exakt definierten Random Copolymers genutzt. Es konnte bereits gezeigt werden, dass auch Blockcopolymere geschaffen werden können, die eine Möglichkeit zur Kombination von Nanostrukturformationen in Blockcopolymeren mit speziellen Funktionaltäten bieten. Folglich sind die speziellen Eigenschaften dieser Funktionalpolymere wie die Fähigkeit zur Photostrukturierung und Verankerung auf Goldsubstraten für nanotechnologische Anwendungen sehr interessant.
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Perfluroaryl azides : Reactivities, Unique Reactions and their Applications in the Synthesis of Theranostic AgentsXie, Sheng January 2015 (has links)
The work centersaround perfluoroaryl azides (PFAAs), and theirability to undergo certain fast and robusttransformations. The chemistry was furtherappliedfor biomedical applications. The first section focuses on the azide-aldehyde-amine cycloaddition using PFAAs. Experimental and computational investigations uncovered a fast azide-enamine cycloaddition to form triazolines, which spontaneously rearrange into stable amidine products. In addition, this transformation was explored in the formulation of pure nanodrugs. Because this reaction can introduce a phenyl and a perfluoroaryl moiety enabling supramolecular interactions near the antibiotic drug, the resulting ciprofloxacin derivatives formed nano-sized aggregates by precipitation, which displayed aggregation-induced emission for bacterial imaging as well as enhanced size-dependent antibacterial efficacy. In the second section, the high electrophilicity of PFAAs was explored to transform azides to aryl amides. The reactivity of PFAAs in the thioacid/azide reaction was studied. In addition, PFAAs were discovered to react with phenylacetaldehyde to form aryl amidesviaan azide-enol cycloaddition, similar tothe perfluoroaryl azide-aldehyde-amine reaction.This strategyof amide synthesiswas furthermoregeneralized through a combination of base-catalyzed azide-enolate cycloaddition reaction and acid-or heat-promoted rearrangement of triazolines. The last section describes a type of azide fluorogens whose fluorescence can be switched on by alight-initiated intramolecular nitrene insertion intoa C-H bond in the neighboring aromaticring. These fluorogenic structures were efficiently accessed via the direct nucleophilic aromatic substitution of PFAAs. / <p>QC 20150903</p>
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Glycopeptide Enrichment Workflows for Downstream Mass Spectrometric AnalysisBodnar, Edward 01 November 2013 (has links)
Mass spectrometry (MS) is a power analytical tool which is capable of analyzing biomolecules in great detail, both structurally and quantitatively. With regards to glycans, special considerations regarding sample preparation are necessary in order to achieve reproducible identification and relative quantification of these analytes. A workflow for isolation at the glycopeptide level and subsequent detection at the glycan level with phenylhydrazine, demonstrated that monoclonal antibodies (mAbs) containing a specific amino acid mutation were able to express approximately an additional 50% of the α2,6 disialylated glycan compared to their non-mutant analogues. In a second experiment using mAbs, an azide modified glycan (Ac4ManAz) was introduced both metabolically and enzymatically during mAb production. This glycan is a precursor in the sialic acid pathway and the azide moiety allows for specific chemistry post-production including the potential for highly specific enrichment. The results of this workflow demonstrated that [100 μM] of Ac4ManAz precursor added to the cell media was necessary for metabolic expression. More complex samples however, may contain multiple sites of glycosylation. To conserve the site of attachment, these molecules are often studied at the glycopeptide level, and require enrichment of glycopeptides to improve the lower signal intensity observed in the presence of co-eluting peptides. Carboxymethyl chitosan (CMCH) as well as amine-functionalized magnetic-nanoparticles (MNP) were developed as novel materials for this purpose. CMCH is naturally occurring, and therefore is cost-effective and readily available. In a 12 protein mixture CMCH demonstrated the bulk enrichment of glycopeptides yielding an approximately 20% higher enrichment of sialylated species as compared to a commercially available glycopeptide kit through the use of tandem mass tags for relative quantification. In the same approach, amine functionalized MNP were produced and used to enrich glycopeptides from tryptic digests. This approach was fast (about 10 mins) and quantitatively demonstrated improved retention for sialylated species. Examples of these techniques and their applications are reported in this work. / October 2015
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Controlling nitric oxide (NO) overproduction : N[omega], N[omega]-dimethylarginine dimethylaminohydrolase (DDAH) as a novel drug targetWang, Yun, 1981- 01 November 2011 (has links)
Nitric oxide (NO) overproduction is correlated with numerous human diseases, such as arthritis, asthma, diabetes, inflammation and septic shock. The enzyme activities of both NO synthase (NOS) and dimethylarginine dimethylaminohydrolase-1 (DDAH-1) promote NO production. DDAH-1 mainly colocalizes in the same tissues as the neuronal isoform of NOS and catabolizes the endogenously-produced competitive inhibitors of NOS, N[omega]-monomethyl-L-arginine (NMMA) and asymmetric N[omega], N[omega]-dimethyl-L-arginine (ADMA). Inhibition of DDAH-1 leads to elevated concentrations of NMMA and ADMA, which subsequently inhibit NOS. To better understand DDAH-1, I first characterized the catalytic mechanism of human DDAH-1, where Cys274, His173, Asp79 and Asp127 form a catalytic center. Particularly, Cys274 is an active site nucleophile and His173 plays a dual role in acid/base catalysis. I also studied an unusual mechanism for covalent inhibition of DDAH-1 by S-nitroso-L-homocysteine (HcyNO), where an N-thiosulfoximide adduct is formed at Cys274. Using a combination of site directed mutagenesis and mass spectrometry, we found that many residues that participate in catalysis also participate in HcyNO mediated inactivation. Following these studies, I then screened a small set of known NOS inhibitors as potential inhibitors of DDAH-1. The most potent of these, an alkylamidine, was selected as a scaffold for homologation. Stepwise lengthening of the alkyl substituent changes an NOS-selective inhibitor into a dual-targeted NOS/DDAH-1 inhibitor then into a DDAH-1 selective inhibitor, as seen in the inhibition constants of N5-(1-iminoethyl)-, N5-(1-iminopropyl)-, N5-(1-iminopentyl)- and N5-(1-iminohexyl)-L-ornithine for neuronal NOS (1.7, 3, 20, >1,900 [mu]M, respectively) and DDAH-1 (990, 52, 7.5, 110 [mu]M, respectively). X-ray crystal structures suggest that this selectivity is likely due to active site size differences. To rank the inhibitors' in vivo potency, we constructed a click-chemistry based activity probe to detect inhibition of DDAH-1 in live mammalian cell culture. In vivo IC50 values for representative alkylamidine based inhibitors were measured in living HEK293T cells. Future application of this probe will address the regulation of DDAH-1 activity in pathophysiological states. In summary, this work identifies a versatile scaffold for developing DDAH targeted inhibitors to control NO overproduction and provides useful biochemical tools to better understand the etiology of endothelial dysfunction. / text
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Investigation of Nucleosome Dynamics by Genetic Code ExpansionHahn, Liljan 10 March 2015 (has links)
No description available.
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Synthèse par cycloaddition 1,3-dipolaire d'hétérocycles et spiro-hétérocycles glycosylés comme inhibiteurs de la glycogène phosphorylase et agents anti-hyperglycémiants : évaluation et tests biologiquesGoyard, David 15 December 2011 (has links) (PDF)
A la suite des nombreux travaux sur l'inhibition de la glycogène phosphorylase (GP) menés au laboratoire et au travers de diverses collaborations, cette thèse décrit en cinq chapitres suivis d'une partie expérimentale détaillée, les dernières avancées en termes de synthèse et d'évaluation biologique des inhibiteurs du site catalytique de la GP. La chapitre I de ce manuscrit est consacrée à la présentation des diabètes et plus particulièrement du diabète de type II dont le traitement, motivation première de ce projet, repose sur la connaissance des mécanismes complexes régulant la glycémie. Les différents inhibiteurs synthétisés sont classés par famille selon leur structure qui associe un aglycone hétérocyclique, susceptible d'affinité pour le canal β proche du site actif de l'enzyme, avec un motif glycopyranosidique, ou glycopyranosylidène dans le cas des motifs spiro. Le chapitre II est consacré aux inhibiteurs spiro-bicycliques tels que les glucopyranosylidène-spiro-1,4,2-oxathiazoles et les glucopyranosylidène-spiro-isoxazolines. Le chapitre III décrit la synthèse de C- et N-glycosyles hétérocycles, principalement des glycopyranosyl-1,2,3-triazoles. Enfin le chapitre IV décrit la fonctionnalisation de 5-halogéno-1,2,3-triazoles 4-substitués par couplages pallado-catalysés qui ont constitué un développement imprévu mais original des travaux. Pour terminer, le chapitre V décrit l'évaluation des molécules préparées en tant qu'inhibiteurs de la glycogène phosphorylase. Les expériences et résultats d'enzymologie, de cristallographie ainsi que les tests cellulaires in vitro et in vivo sur le rat sont présentés
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From Probes to Cell Surface Labelling: Towards the Development of New Chemical Biology Compounds and MethodsLegault, Marc 29 June 2011 (has links)
Chemical biology encompasses the study and manipulation of biological system using chemistry, often by virtue of small molecules or unnatural amino acids. Much insight has been gained into the mechanisms of biological processes with regards to protein structure and function, metabolic processes and changes between healthy and diseased states. As an ever expanding field, developing new tools to interact with and impact biological systems is an extremely valuable goal. Herein, work is described towards the synthesis of a small library of heterocyclic-containing small molecules and the mechanistic details regarding the interesting and unexpected chemical compounds that arose; an alternative set of non-toxic copper catalyzed azide-alkyne click conditions for in vivo metabolic labelling; and the synthesis of an unnatural amino acid for further chemical modification via [3+2] cycloadditions with nitrones upon incorporation into a peptide of interest. Altogether, these projects strive to supplement pre-existing methodology for the synthesis of small molecule libraries and tools for metabolic labelling, and thus provide further small molecules for understanding biological systems.
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