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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
41

Estudos biofísicos de chaperonas de secreção e de interações proteína-ligante / Biophysical studies on secretion chaperones and protein-ligand interactions

Prando, Alessandra, 1980- 20 August 2018 (has links)
Orientador: Ljubica Tasic / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Química / Made available in DSpace on 2018-08-20T16:55:17Z (GMT). No. of bitstreams: 1 Prando_Alessandra_D.pdf: 9977861 bytes, checksum: 15d25bce7d95433f95b938e68fdeaac8 (MD5) Previous issue date: 2012 / Resumo: Até o momento, pouco se sabe sobre os mecanismos de virulência da bactéria Xanthomonas axonopodis pv. citri (XAC), agente causador do cancro cítrico. Acredita-se que chaperonas de secreção (CS) estão envolvidas no processo de patogenicidade de XAC primeiramente formando complexos com fatores de virulência e auxiliando no encaminhamento desses para os sistemas de secreção utilizando o ATP como fonte de energia. Neste trabalho foram adquiridos dados de fluorescência de emissão, dicroísmo circular, desenovelamento térmico e de ressonância magnética nuclear de H NMR e de 2D {N,H} HSQC de duas proteínas da XAC, a XAC1990 (FlgN) e XACb0033. Para ambas proteínas foram propostas estruturas 3D usando a análise de footprinting com restrições SASA e rmsd. Para as estruturas propostas foi verificado que os dados de fluorescência corroboram com a estrutura 3D não ocorrendo o mesmo para os dados de CD e NMR que revelaram baixo conteúdo helicoidal além de ausência de estrutura 3 D. A interação da proteína FlgN com a sua proteína parceira FlgK também foi sugerida através das análises de CD e fluorescência. Na segunda parte do trabalho foram estudadas as interações entre a proteína Hsp90 da laranja com diferentes ligantes aplicando a técnica de Saturation Transfer Difference (STD-NMR) e espectroscopia de fluorescência. Estas análises revelaram dados que corroboraram com o modelo proposto e, além disso, indicaram que os hidrogênios H-8 e H-2 da adenina e H-1'da ribose estão localizados no sítio ligante da proteína com os fosfatos orientados para fora. Através da fluorescência foram calculados os valores de Kd e foi verificado que a geldanamicina é um potente inibidor de Hsp90 da laranja / Abstract: So far, the Xanthomonas axonopodis pv. citri (XAC) mechanisms of bacterial virulence is unknown. It is believed that secretion chaperones (CS) are involved in the XAC's virulence process by first forming complexes with virulence factors, and assisting in their presentation to corresponding secretion systems using ATP as a source of energy. Fluorescence emission, circular dichroism, thermal unfolding and nuclear magnetic resonance NMR H and 2D {N,H} HSQC data from two proteins of XAC, XAC1990 (FlgN) and XACb0033 were collected. For both proteins, 3D structures were proposed using the footprinting analysis with RMSD and SASA restrictions. For the proposed structures were verified which the fluorescence data were consistent with the 3D structure. The CD and NMR data revealed low-helical content and absence of 3D structure. The interaction of the protein FlgN with its partner, FlgK, was suggested by CD and fluorescence analysis. In the second part, the interactions between the orange's Hsp90 protein with different ligants using Saturation Transfer Difference (STD-NMR) and fluorescence spectroscopy techniques were studied. These analyzes revealed which the data were consistent with the proposed model and moreover showed that the adenine's hydrogens H-8 and H-2 and ribose's hydrogen H-1'are located in the protein binding site with the phosphate driven out. By fluorescence values were calculed Kd and it was verified that geldanamycin is a potent inhibitor of orange's Hsp90 / Doutorado / Quimica Organica / Doutor em Ciências
42

Nouvelles méthodologies en spectrométrie de masse native et mobilité ionique pour la caractérisation structurale de macrobiomolécules et de leurs complexes associés / Novel methodologies in native mass spectrometry and ion mobility for structural characterization of macrobiomolecules and their related complexes

Stojko, Johann 11 March 2016 (has links)
Ce travail de thèse porte sur le développement de méthodes en spectrométrie de masse (MS) et mobilité ionique (IM-MS) supramoléculaires pour la caractérisation fine de complexes protéine-ligand et d’assemblages protéiques hétérogènes de hauts poids moléculaires. L’optimisation instrumentale apportée à l’étude de ces systèmes, permet d’étendre le potentiel de ces deux approches en biologie structurale. Le criblage de complexes protéine-ligand permet ici une détermination de leurs propriétés d’interaction et la mise en évidence de subtils changements de conformation induits, pouvant être suivis au cours du temps. L’application de ce couplage à l’analyse de complexes multi-protéiques, réfractaires aux techniques conventionnelles, donne accès à la topologie de ces assemblages, facilitant la proposition de modèles structuraux. Enfin, l’apport récent de la haute résolution en MS native est ici illustré à travers l’étude de protéines complexes et hétérogènes : les anticorps thérapeutiques et leurs conjugués. Ces développements permettent de repousser certaines limites en MS native et IM-MS native, élargissant leurs perspectives d’application dans la recherche et l’industrie pharmaceutique. / This PhD thesis aims at developing methods in native mass spectrometry (MS) combined with ion mobility (IM-MS) to characterize protein-ligand complexes and large protein assemblies. Fine-tuning of instrumental settings allowed expanding the scope of these approaches in structural biology. Real-time monitoring of protein-ligand complexes by native MS and IM-MS enabled to screen their binding properties while depicting subtle conformational changes induced upon binding. Applying these methods to refractory multi-protein complexes provided insights about their topology, making structural modeling easier. Finally, benefits from high-resolution native MS were highlighted through the characterization of heterogeneous systems, including monoclonal antibodies and their drug conjugates. Here, these developments enable to push some technical limits one step forward, increasing the potential of native MS and IM-MS both in academic research and pharmaceutical industry.
43

Analysis Of Protein Purification By Affinity Chromatography

Sridhar, P 05 1900 (has links) (PDF)
No description available.
44

Exploring non-covalent interactions between drug-like molecules and the protein acetylcholinesterase / En studie av icke-kovalenta interaktioner mellan läkemedelslika molekyler och proteinet acetylkolinesteras

Berg, Lotta January 2017 (has links)
The majority of drugs are small organic molecules, so-called ligands, that influence biochemical processes by interacting with proteins. The understanding of how and why they interact and form complexes is therefore a key component for elucidating the mechanism of action of drugs. The research presented in this thesis is based on studies of acetylcholinesterase (AChE). AChE is an essential enzyme with the important function of terminating neurotransmission at cholinergic synapses. AChE is also the target of a range of biologically active molecules including drugs, pesticides, and poisons. Due to the molecular and the functional characteristics of the enzyme, it offers both challenges and possibilities for investigating protein-ligand interactions. In the thesis, complexes between AChE and drug-like ligands have been studied in detail by a combination of experimental techniques and theoretical methods. The studies provided insight into the non-covalent interactions formed between AChE and ligands, where non-classical CH∙∙∙Y hydrogen bonds (Y = O or arene) were found to be common and important. The non-classical hydrogen bonds were characterized by density functional theory calculations that revealed features that may provide unexplored possibilities in for example structure-based design. Moreover, the study of two enantiomeric inhibitors of AChE provided important insight into the structural basis of enthalpy-entropy compensation. As part of the research, available computational methods have been evaluated and new approaches have been developed. This resulted in a methodology that allowed detailed analysis of the AChE-ligand complexes. Moreover, the methodology also proved to be a useful tool in the refinement of X-ray crystallographic data. This was demonstrated by the determination of a prereaction conformation of the complex between the nerve-agent antidote HI-6 and AChE inhibited by the nerve agent sarin. The structure of the ternary complex constitutes an important contribution of relevance for the design of new and improved drugs for treatment of nerve-agent poisoning. The research presented in the thesis has contributed to the knowledge of AChE and also has implications for drug discovery and the understanding of biochemical processes in general.
45

Native mass spectrometry and complementary techniques to characterize biological macromolecular assemblies

Norris, Andrew S. January 2021 (has links)
No description available.
46

Structural and Biochemical Studies of Protein-Ligand Interactions: Insights for Drug Development

Mishra, Vidhi January 2013 (has links)
No description available.
47

Mapping Allosteric Sites and Pathways in Systems Unamenable to Traditional Structure Determination / Mapping Allostery in Unconventional Systems

Boulton, Stephen January 2018 (has links)
Allostery is a regulatory process whereby a perturbation by an effector at one discrete locus creates a conformational change that stimulates a functional change at another. The two sites communicate through networks of interacting residues that respond in a concerted manner to the allosteric perturbation. These allosteric networks are traditionally mapped with high resolution structure determination techniques to understand the conformational changes that regulate protein function as well as its modulation by allosteric ligands and its dysfunction caused by disease-related mutations (DRMs). However, high resolution structural determination techniques, such as X-ray crystallography, cryo-electron microscopy and nuclear Overhauser effect NMR spectroscopy are not always amenable for systems plagued by poor solubility and line broadening caused by μs-ms dynamics or systems where allostery relies primarily on dynamical rather than structural changes. This dissertation discusses methodologies to map the allosteric sites and pathways for such challenging systems. The foundation of this approach is to model allosteric pathways in the context of their respective thermodynamic cycles. In chapter 2, the thermodynamic cycle of a DRM in the hyperpolarization-activated cyclic nucleotide-gated ion channel 4 (HCN4) is analyzed with respect to structure, dynamics and kinetics, revealing how the DRM remodels the free energy landscape of HCN4 and results in a loss-of-function disease phenotype. In chapter 3, the mechanism of action of an uncompetitive inhibitor for the exchange protein activated by cAMP is elucidated by characterizing its selectivity for distinct conformations within the thermodynamic cycle that are trapped using a combination of mutations and ligand analogs. In chapter 4, we discuss two new protocols for the chemical shift covariance analysis (CHESCA). The CHESCA is an approach that identifies allosteric signaling pathways by measuring concerted residue responses to a library of chemical perturbations that stabilize conformational equilibria at different positions. Overall, the approaches discussed in this dissertation are widely applicable for mapping the mechanisms of allosteric perturbations that arise from ligand binding, post-translational modifications and mutations, even in systems where traditional structure determination techniques remain challenging to implement. / Thesis / Doctor of Philosophy (PhD) / Allostery is a regulatory mechanism for proteins, which controls functional properties of one distinct site through the perturbation of another distinct, and often distant, site. The two sites are connected via a series of residues that undergo conformational changes once perturbed by the allosteric effector. Mapping these communication pathways reveals mechanisms of protein regulation, which are invaluable for developing pharmacological modulators to target these pathways or for understanding the mechanisms of disease mutations that disrupt these pathways. Allosteric pathways have been traditionally determined using structure determination approaches that provide a static snapshot of the protein’s structure. However, these approaches are typically not effective when allostery relies extensive changes in dynamics. The goal of this thesis was to develop methods to characterize systems that are dynamic or otherwise unsuitable for traditional structure determination. Herein, we utilize NMR spectroscopy to analyze the allosteric mechanisms of three cAMP-binding proteins involved in cardiovascular health.
48

Rôle du domaine extracellulaire d’ABCG2 dans l’homéostasie des porphyrines / Role of the extracellular domain of ABCG2 in porphyrin homeostasis

Desuzinges-Mandon, Elodie 23 November 2010 (has links)
ABCG2 est un transporteur de la famille ABC impliqué dans le phénotype de résistance aux drogues développé par certaines cellules, par exemple les cellules cancéreuses. Ce transporteur a aussi un rôle physiologique de détoxication de composés endogènes, notamment les porphyrines, molécules indispensables mais qui présentent une toxicité potentielle. Cette toxicité nécessite une prise en charge particulière, évitant à ces composés d’être libres en solution. Dans ce contexte, nous avons fait l’hypothèse qu’ABCG2 pourrait participer à cette détoxication en limitant l’accumulation des porphyrines dans les cellules en les présentant à un partenaire extracellulaire. Nous montrons qu’ABCG2 transporte de l’hème ainsi que certains de ses dérivés et précurseurs et que ces porphyrines, contrairement aux autres substrats d’ABCG2, se fixent sur un domaine extracellulaire spécifique d’ABCG2, ECL3, composé d’environ 70 acides aminés. L’affinité d’ECL3 pour les porphyrines est de 0,5 à 3,5 μM, suffisamment affine pour permettre leur fixation après transport.Nous montrons aussi que l’albumine sérique humaine, impliquée dans la détoxication de l’hème, récupère les porphyrines fixées sur ECL3 par une interaction directe avec ABCG2. L’ensemble de ce travail a donc permis d’une part de mieux comprendre le rôle d’ABCG2 dans la régulation de l’homéostasie des porphyrines, notamment l’hème, et d’autre part, de façon originale, d’identifier le mécanisme moléculaire par lequel cette détoxication s’effectue. / ABCG2 belongs to the ABC-transporter family, involved in drug resistance developed by cells, notably cancer cells. This transporter has also a physiological role of endobiotic detoxification, in particular porphyrins that are essential but potentially toxic molecules. This toxicity implies a specific handle, to avoid them to remain free in solution. In that context, we hypothesized that ABCG2 participate to this detoxification, limiting the intracellular porphyrin accumulation by presenting them to an extracellular partner. We show that ABCG2 transports heme and some of its derivatives and precursors. Interestingly, these porphyrins, unlike other ABCG2 (non-porphyric) substrates, can bind to an extracellular domain, specific of ABCG2, ECL3, 70 residues-long. ECL3 displays affinities for porphyrins in the range of 0.5 to 3.5 μM, high enough to allow their binding after transport. We also show that human serum albumin, implicated in heme detoxification, releases porphyrins bound to ECL3 by a direct interaction with ABCG2. This work established a better comprehension of ABCG2 role in porphyrin and in particular heme homeostasis regulation. In addition, our results contribute to elucidate part of the molecular mechanism by which such regulation is carried out.
49

Synthèse de mimes de mycolactones pour l’étude mécanistique de l’ulcère de Buruli / Synthesis of mycolactone mimetics for the mechanistic study of Buruli ulcer

Tresse, Cédric 29 September 2014 (has links)
Ce projet de recherche se focalise sur les infections par mycobacterium ulcerans (maladie de l’ulcère de Buruli), une maladie de la peau dévastatrice caractérisée par la formation de lésions nécrotiques progressives et l’absence d’une réponse inflammatoire. Bien que négligée, cette infection est la troisième maladie mycobactérienne la plus répandue après la tuberculose et la lèpre et des cas sont rapportés dans plus de 30 pays à travers le monde. Mycobacterium ulcerans sécrète une toxine polycétidique complexe, appelée mycolactone A/B, qui est directement responsable des effets pathogènes de la maladie. Depuis sa découverte, les propriétés biologiques inhabituelles de la mycolactone A/B ont suscité de nombreux efforts de recherche dans différents domaines. Dans ce contexte, ce projet s’intéresse à l’élucidation du mécanisme d’action des mycolactones en utilisant la synthèse totale comme outil principal. Dans cette optique, notre équipe a mis en place une voie de synthèse permettant un accès facile et robuste à différents mimes de mycolactone. L’utilisation de cette méthode a conduit à la préparation de 13 mimes de la toxine au cours de cette thèse. D’autre part notre équipe s’intéresse également à la préparation de mimes possédant un ou plusieurs atomes de fluor. Ces derniers présentent un intérêt particulier pour améliorer la compréhension des interactions ayant lieu entre la toxine et sa cible cellulaire. Les travaux réalisés autours de la synthèse de mycolactones fluorés ont conduit à la mise au point d’une méthode générale et simple pour introduire un groupe trifluorométhyle sur un alcyne terminal, permettant ainsi des modulations inédites de la structure de la toxine. / This research project focuses on mycobacterium ulcerans infection (Buruli ulcer disease), a severe skin disease characterized by the formation of progressive necrotic lesions and the lack of an acute inflammatory response. Although neglected, this infection is the third most common mycobacteriosis after Mycobacterium tuberculosis and Mycobacterium leprae, and cases are reported in more than 30 countries worldwide. Mycobacterium ulcerans secretes a complex polyketidic macrolide, called mycolactone A/B, which is directly involved in the biological effects of the disease. Since its discovery, the unusual biology triggered by this toxin has spurred research efforts. In this context, this research project aims at a better understanding of mycolactone A/B molecular interactions by using total synthesis as main tool. To this end, our research team has developed an efficient synthetic pathway allowing the preparation of different mimetics of the toxin. This synthesis has been used to prepare thirteen new mycolactone mimetics during this thesis. Moreover our team has also been interested in the synthesis of fluorinated mycolactone analogs. Such fluorinated mycolactones are of great interest to improve the interactions that occur between the toxin and its biological binding site. Work in this field led to the development of a simple and general method to introduce a trifluoromethyl group onto a terminal alkyne, allowing novel modulation of the structure of the toxin.
50

Développements en spectrométrie de masse pour l’étude des complexes biologiques / Developments of mass spectrometry for the study of biological complexes

Nguyen Huynh, Nha Thi 12 October 2015 (has links)
L’élucidation des interactions non-covalentes des complexes biologiques revêt d’une importance majeure dans la compréhension du fonctionnement cellulaire. L’objectif de ce travail de thèse est d’approfondir les développements de la spectrométrie de masse (MS) pour l’étude de ces complexes, que ce soit par MALDI-MS (la désorption-ionisation laser assistée par matrice) ou par ESI-MS (l’ionisation électrospray). Ce travail s’est articulé autour de trois axes : i) étude de la stœchiométrie et de la topologie du complexe SAGA HAT (Spt-Ada-Gcn5 Acétyltransferase, module Histone Acétyl Transferase) par pontage chimique couplé à la MS ; ii) suivi de la dimérisation des complexes formés par RAR-RXR (récepteur de l’acide rétinoïque - récepteur X des rétinoïdes) avec différents ADNs ; iii) mesure de la constante de dissociation des complexes RXR-ligand. Les méthodologies développées ont permis de repousser le potentiel de la MS et d’obtenir des informations structurales des complexes biologiques. / Elucidation of non-covalent interactions of biological complexes takes on great importance for the understanding of cellular function. The purpose of this thesis is a further development of mass spectrometry (MS) for the study of these complexes, either by MALDI-MS (matrix-assisted laser desorption-ionization) or by ESI-MS (electrospray ionization). This work was focused on three main lines: i) study of the stoichiometry and the topology of SAGA HAT (Spt-Ada-Gcn5 Acetyltransferase, Histone Acetyl Transferase module) complex by chemical cross-linking coupled to MS; ii) monitoring the dimerization of the complexes formed by RAR-RXR (retinoic acid receptor - retinoid X receptor) with different DNAs; iii) measuring the dissociation constant of RXR-ligand complexes. The developed methodologies made it possible to expand the potential of MS and get insight into structure of biological complexes.

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