Global ETD Search

1	Etudes par RMN des L,D-transpeptidases bactériennes : structure, dynamique et compréhension de leur inhibition par les beta-lactames / NMR study of bacterial L,D-transpeptidases : structure, dynamics and insights into their inhibition by beta-lacams Lecoq, Lauriane 29 November 2012 (has links) L'étape finale de biosynthèse du peptidoglycane est catalysée par les D,D-transpeptidases (PBPs), l'une des cibles principales des antibiotiques de type beta-lactame. Récemment, il a été montré qu'une nouvelle classe d'enzymes, les L,D-transpeptidases (LDts), permet de contourner l'inhibition des PBPs. Ces LDts ont été identifiées tant dans des bactéries résistantes aux beta-lactames que dans des formes dormantes de Mycobacterium tuberculosis. Les seuls beta-lactames capables de les inhiber, les carbapénèmes, forment une liaison covalente avec la cystéine catalytique des LDts. Ni le mécanisme de cette inactivation, ni la spécificité de ces enzymes pour les carbapénèmes ne sont toutefois expliqués à ce jour. Le but du présent travail consiste en l'investigation par RMN du mécanisme d'acylation des LDts par ces antibiotiques. Dans ce contexte, la première partie de cette thèse s'intéresse à la compréhension actuelle de l'émergence de ce phénomène de résistance. La seconde partie traite des principes de la RMN et des implémentations développées pour étudier la structure, la thermodynamique et la dynamique des LDts. La troisième et dernière partie démontre le succès de l'approche RMN dans l'étude des diverses étapes de la réaction d'acylation, à travers une étude détaillée de l'apoenzyme, de complexes non covalents avec différents beta-lactames, et de l'enzyme acylée par un carbapénème. Au cours de cette étude, la structure du site actif de l'apoenzyme de Bacillus subtilis a été affinée par rapport à une étude cristallographique antérieure. Pour cette enzyme et son pendant chez Enterococcus faecium, nous avons démontré que la spécificité pour les carbapénèmes n'intervient pas au stade de la formation du complexe non covalent. Pour finir, la formation de la liaison covalente entre LDt et carbapénème induit un réarrangement conformationnel substantiel et une augmentation de la flexibilité de l'enzyme. / The final cross-linking step of the peptidoglycan synthesis is usually catalyzed by D,D-transpeptidases (PBPs), one of the main targets of beta-lactam antibiotics. Recently, it was shown that these PBPs can be by-passed by a novel class of enzymes, the L,D-transpeptidases (LDts), identified in beta-lactam-resistant bacteria as well as in dormant forms of Mycobacterium tuberculosis. The only beta-lactams enable to inactivate these enzymes belong to the carbapenem class. The beta-lactam ring of this antibiotic family then covalently binds the catalytic cysteine of the LDt. Neither the mechanism of this reaction nor the specificity for carbapenems are yet understood. The aim of the present work is to investigate the acylation mechanism of LDts with carbapenems by NMR. In this context, the first part of this thesis focuses on the current biological understanding of the emergence of this resistance pathway. The second part deals with the NMR principles and the implementations developed to study the structure, thermodynamics and dynamics of LDts. The third part demonstrates that NMR is successful in studying all the steps of the acylation reaction. For this purpose, the LDt apoenzyme, the non-covalent complex with various beta-lactams, and the LDt-carbapenem acylenzyme were thoroughly investigated. The structure of the active site of the Bacillus subtilis apoenzyme was refined with respect to a previous crystallographic study. For the latter and the Enterococcus faecium enzymes, we showed that the carbapenem specificity does not occur at the stage of the non-covalent binding. In contrast to non-covalent interactions, the formation of the covalent bond between LDts and carbapenems induces substantial conformational rearrangement and increased flexibility in the enzyme. Transpeptidase Résistance aux antibiotiques Peptidoglycane Beta-lactame Transpeptidase Antibiotic resistance Peptidoglycan Beta-lactame
2	Sortases: Keystones to Virulence and Targets for Anti-Infective Therapy Melvin, Jeffrey A. January 2012 (has links) <p>Gram-positive pathogens, such as <italic>Streptococcus pyogenes</italic> and <italic>Staphylococcus aureus</italic>, are etiological agents of a large array of human diseases. Unfortunately, our ability to treat these infections is increasingly limited due to the development of bacterial resistance to many existing therapies. Thus, novel targets for antimicrobial development are urgently needed. An attractive candidate for a new class of anti-virulence chemotherapeutics is the sortase class of enzymes. Sortases are extracellular transpeptidases unique to Gram-positive bacteria. Their function is to covalently attach secreted virulence factors to the bacterial cell wall. Deletion or inhibition of sortases results in severe attenuation of bacteria for infection. In order to develop novel effective antimicrobial agents, a robust understanding of the biological and chemical mechanisms of the target are required. To this end, this dissertation endeavors to further illuminate the biochemical mechanism of sortase enzymes and to extend the current knowledge of the roles of sortases and their substrates during infection.</p><p>Through steady-state kinetics, active site reactivity measurements, three-dimensional structure determination via X-ray crystallography, and computational modeling of substrate binding, the basic enzyme mechanism of <italic>S. pyogenes</italic> sortase A (SrtA) has been revealed. In general, <italic>S. pyogenes</italic> SrtA displays many of the same mechanistic characteristics as previously studied sortases, including a reverse protonation mechanism, a conserved tertiary structure arrangement, and utilization of similar substrate binding interfaces and conserved active site residue functions. These findings suggest a general sortase mechanism, conserved among classes and species.</p><p>Initial steps have also been taken to characterize <italic>S. pyogenes</italic> sortase C (SrtC). SrtC enzymes are unique in that they covalently polymerize secreted proteins, rather than attach them to peptidoglycan. Full length and truncation mutant constructs of SrtC and its substrate, T3, and peptide substrate mimics have been produced in soluble form for use in kinetic assays. Additionally, initial crystallization conditions have been identified for <italic>S. pyogenes</italic> SrtC towards the goal of three-dimensional structure determination. A homology model of the structure has also been produced, displaying many of the general features observed for other sortase enzymes.</p><p>Additionally, a computational analysis of the mechanism of isopeptide bond formation in <italic>S. pyogenes</italic> SPy0128, a substrate of <italic>S. pyogenes</italic> SrtC, has been performed. Isopeptide bonds have previously been found in structural studies of Gram-positive bacterial adhesins in each domain of these multi-domain proteins. The bonds are typically formed between conserved lysine and asparagine residues, and formation is likely catalyzed by adjacent conserved glutamates. A direct nucleophilic attack mechanism, starting from an inverse protonation state, is supported in this study. Of note, there appears to be temporal regulation of isopeptide bond formation in the different domains of <italic>S. pyogenes</italic> SPy0128, with the C-terminal domain isopeptide bond forming prior to or simultaneously with the N-terminal domain isopeptide bond.</p><p>Previous studies suggest that SrtA activity is required for <italic>S. aureus</italic> to survive phagocytosis by a macrophage. The production of reactive oxygen species by professional phagocytes could lead to inhibition of SrtA via oxidation of a conserved nucleophilic cysteine residue in the active site. Through determination of inhibition kinetics, identification of oxidative modifications, reduction potential measurements, and analyses of SrtA in vivo activity in the presence of reactive oxygen species, it has been demonstrated that <italic>S. aureus</italic> SrtA is resistant to oxidative inhibition. These findings support SrtA activity inside the phagolysosome of a professional phagocyte and likely contribute to the ability of <italic>S. aureus</italic> to evade the innate immune system.</p><p>The roles of sortases and their substrates during <italic>S. aureus</italic> survival inside professional phagocytes have not been thoroughly investigated. Through analysis of the regulation of these surface proteins under phagolysosomal conditions and macrophage phagocytosis survival assays, initial characterization of the functions of sortases and their substrates in this environment has been completed. Previous studies have suggested a role for SrtA and its substrate, Protein A, and these genes and two other sortase-substrates were upregulated in response to phagolysosomal conditions. However, neither sortases nor their substrates demonstrated a direct function in phagocytosis survival. These findings imply a complex interplay between <italic>S. aureus</italic> and professional phagocytes. Further studies are necessary to delineate the direct activities of surface anchored proteins during phagocytosis of <italic>S. aureus</italic> by professional phagocytes.</p> / Dissertation Biochemistry sortase staphylococcus aureus streptococcus pyogenes transpeptidase virulence factor
3	Étude de la distribution, de la clonalité et caractérisation des campylobacters isolés de poulets à griller et d'humains Nadeau, Éric January 2003 (has links) Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal. Campylobacter jejuni Campylobactériose Poulet Humain Distribution Risque Virulence Gamma-glutamyl transpeptidase GGT
4	Synthèse et études cinétiques de substrats analogues et d'inhibiteurs de l'étape d'acylation de la [gamma]-glutamyl transpeptidase Lherbet, Christian January 2003 (has links) Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal. Enzyme [gamma]-glutamyl transpeptidase Inhibition Cinétiques Cyanate de potassium Cartographie Glutathion Sulfoxyde Phosphonamide
5	Transsulfuration Pathway Defects and Increased Glutathione Degradation in Severe Acute Pancreatitis. Rahman, S.H., Srinivasan, Asha R., Nicolaou, Anna January 2009 (has links) no / Glutathione depletion is a consistent feature of the progression of mild to severe acute pancreatitis. In this study, we examined the temporal relationship between cysteine, homocysteine, and cysteinyl-glycine levels; total reduced erythrocyte glutathione; gamma-glutamyl transpeptidase activity; and disease severity. Initially, cysteine concentration was low, at levels similar to those of healthy controls. However, glutathione was reduced whilst cysteinyl glycine and gamma-glutamyl transpeptidase activity were increased in both mild and severe attacks. As the disease progressed, glutathione and cysteinyl glycine were further increased in mild attacks and cysteine levels correlated with homocysteine (r = 0.8, P < 0.001) and gamma-glutamyl transpeptidase activity (r = 0.75, P < 0.001). The progress of severe attacks was associated with glutathione depletion, reduced gamma-glutamyl transpeptidase activity, and increased cysteinyl glycine that correlated with glutathione depletion (r = 0.99, P = 0.01). These results show that glutathione depletion associated with severe acute pancreatitis occurs despite an adequate cysteine supply and could be attributed to heightened oxidative stress coupled to impaired downstream biosynthesis. Sulfur amino acids Oxidative stress Gamma glutamyl transpeptidase Acute pancreatitis Glutathione depletion Homocysteine Cysteine
6	The Design and Synthesis of Small Molecule Protein Inhibitors as Potential Cancer Therapeutics Regan, Nicholas Bauman 20 July 2011 (has links) No description available. Pharmacy Sciences FK506 Binding Proteins, FBKP
7	Etudes par RMN des L,D-transpeptidases bactériennes : structure, dynamique et compréhension de leur inhibition par les beta-lactames Lecoq, Lauriane 29 November 2012 (has links) (PDF) L'étape finale de biosynthèse du peptidoglycane est catalysée par les D,D-transpeptidases (PBPs), l'une des cibles principales des antibiotiques de type beta-lactame. Récemment, il a été montré qu'une nouvelle classe d'enzymes, les L,D-transpeptidases (LDts), permet de contourner l'inhibition des PBPs. Ces LDts ont été identifiées tant dans des bactéries résistantes aux beta-lactames que dans des formes dormantes de Mycobacterium tuberculosis. Les seuls beta-lactames capables de les inhiber, les carbapénèmes, forment une liaison covalente avec la cystéine catalytique des LDts. Ni le mécanisme de cette inactivation, ni la spécificité de ces enzymes pour les carbapénèmes ne sont toutefois expliqués à ce jour. Le but du présent travail consiste en l'investigation par RMN du mécanisme d'acylation des LDts par ces antibiotiques. Dans ce contexte, la première partie de cette thèse s'intéresse à la compréhension actuelle de l'émergence de ce phénomène de résistance. La seconde partie traite des principes de la RMN et des implémentations développées pour étudier la structure, la thermodynamique et la dynamique des LDts. La troisième et dernière partie démontre le succès de l'approche RMN dans l'étude des diverses étapes de la réaction d'acylation, à travers une étude détaillée de l'apoenzyme, de complexes non covalents avec différents beta-lactames, et de l'enzyme acylée par un carbapénème. Au cours de cette étude, la structure du site actif de l'apoenzyme de Bacillus subtilis a été affinée par rapport à une étude cristallographique antérieure. Pour cette enzyme et son pendant chez Enterococcus faecium, nous avons démontré que la spécificité pour les carbapénèmes n'intervient pas au stade de la formation du complexe non covalent. Pour finir, la formation de la liaison covalente entre LDt et carbapénème induit un réarrangement conformationnel substantiel et une augmentation de la flexibilité de l'enzyme. Transpeptidase Résistance aux antibiotiques Peptidoglycane Beta-lactame
8	Análise de moléculas envolvidas no metabolismo de nitrogênio no fungo patogênico humano Paracoccidioides brasiliensis / Analysis of molecules involved in nitrogen metabolism of the human pathogenic fungi Paracoccidioides brasiliensis Silva, Lana OHara Souza 22 February 2017 (has links) Submitted by Erika Demachki (erikademachki@gmail.com) on 2017-03-14T19:03:25Z No. of bitstreams: 2 Dissertação - Lana OHara Souza Silva - 2017.pdf: 3124489 bytes, checksum: 38e1e83b1c39e6954300e0cd3e709f2a (MD5) license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) / Approved for entry into archive by Luciana Ferreira (lucgeral@gmail.com) on 2017-03-20T12:27:41Z (GMT) No. of bitstreams: 2 Dissertação - Lana OHara Souza Silva - 2017.pdf: 3124489 bytes, checksum: 38e1e83b1c39e6954300e0cd3e709f2a (MD5) license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) / Made available in DSpace on 2017-03-20T12:27:41Z (GMT). No. of bitstreams: 2 Dissertação - Lana OHara Souza Silva - 2017.pdf: 3124489 bytes, checksum: 38e1e83b1c39e6954300e0cd3e709f2a (MD5) license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) Previous issue date: 2017-02-22 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES / The Paracoccidioides genus is composed of thermodimorphic fungus that causes paracoccidioidomycosis (PCM), an endemic human systemic mycosis in Latin America. These organisms grow as mycelium in temperatures below 28 °C and as yeast form in temperatures above 37 °C. Nitrogen is an important element in this microorganism’s nutrition that participates in the synthesis of proteins, nucleic acids and others biomolecules. In this regard, nitrogen uptake and metabolism are essential to growth and fungal establishment. When nitrogen levels and sources such as glutamine and ammonia concentration are limited, pathogenic fungus use a regulation system called Nitrogen Catabolic Repression that induces the expression of genes encoding permeases and enzymes required for the catabolism of secondary nitrogen sources, such as formamidase, gamma-glutamiltranspeptidase and urease. Gamma-glutamiltranspeptidase is an enzyme that catalyzes the first reaction of glutationa degradation and it has been the target of several studies about nitrogen starvation in various fungi. It has been observed that the expression of the gene encoding this enzyme was induced in limiting conditions of nitrogen and was repressed when the availability of nitrogen was high. Urease is an enzyme that catalyzes the degradation of urea in ammonia and carbonic acid. This enzyme is already known as a virulence factor in fungi such as Cryptococcus. neoformans, and also has been the target of studies about nitrogen starvation. In this study we expressed gamma-GT and urease proteins from Paracoccidioides brasiliensis, isolate Pb18, in Escherichia coli. The gene coding for Ggt and Ure were cloned in pET32a expression vector, and used for E. coli pLysS transformation. The recombinant proteins produced were shown to be catalytically active. Together, data obtained in this work could add knowledge about the role of gamma-GT and urease and can be used as a foundation for complementary experiments regarding nitrogen metabolism regulation, as well as in Paracoccidioides spp pathogenesis. / Resumo: O gênero Paracoccidioides é composto por fungos termodimórficos que causam a paracoccidioidomicose (PCM), uma micose sistêmica humana endêmica na América Latina. Quando cultivados em temperaturas menores que 28 °C o fungo cresce como micélio e em temperaturas em torno de 37 °C, como levedura. O nitrogênio é um importante nutriente para os micro-organismos, pois participa da síntese de proteínas, ácidos nucléicos e outras biomoléculas. Nesse sentido, a captação e o metabolismo de nitrogênio são essenciais para o crescimento e o estabelecimento do fungo no hospedeiro. Quando os níveis de nitrogênio e fontes como glutamina e amônia estão em concentrações limitantes, os fungos patogênicos utilizam um sistema de regulação chamado Repressão Catabólica de Nitrogênio que induz a expressão de genes que codificam permeases e enzimas necessárias para o catabolismo de fontes secundárias de nitrogênio como a formamidase, a gama-glutamil transpeptidase e a urease. A gama-glutamil transpeptidase é uma enzima que catalisa a primeira reação da degradação da glutationa. Ela tem sido alvo de estudos de privação de nitrogênio em diversos fungos, nos quais foi observada uma alta expressão do gene codificador dessa enzima em condições limitantes de nitrogênio, enquanto que, em alta disponibilidade de nitrogênio a sua expressão era reprimida. A urease é uma enzima que degrada uréia em amônia e ácido carbônico. Ela já é conhecida por ser um fator de virulência em alguns fungos, como Cryptococcus neoformans, e também tem sido alvo de estudos de privação de nitrogênio. Neste estudo nós expressamos as proteínas gama-GT e urease de Paracoccidioides brasiliensis, isolado Pb18, em sistema heterólogo bacteriano de Escherichia coli. O fragmento dos genes codificadores de Ggt e Ure foram clonados em vetor de expressão pET32a e os respectivos clones foram utilizados na transformação de células de E. coli pLySs. As proteínas recombinantes produzidas mostraram estar cataliticamente ativas. Os dados obtidos neste trabalho puderam acrescentar conhecimentos sobre as enzimas gama-GT e urease e podem ser usados como base para experimentos complementares em relação à regulação do metabolismo de nitrogênio bem como na patogênese de Paracoccidioides spp. Repressão catabólica de nitrogênio Clonagem Atividade enzimática Gama-glutamil transpeptidase Urease Nitrogen catabolic repression Cloning Enzymatic activity Gamma glutamiltranspeptidase

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