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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.
121

Contribution à l'étude des P450 impliqués dans la biosynthèse des furocoumarines / Study of P450 involved in furocoumarin biosynthesis

Larbat, Romain 30 May 2006 (has links)
Les furocoumarines sont des phytoalexines offrant un potentiel thérapeutique important. Les travaux présentés ici portent sur les cytochromes P450 participant à leur voie de biosynthèse. Une étude «structure-fonction» de la cinnamate-4-hydroxylase (C4H) a été réalisée pour identifier les déterminants de la faible sensibilité de la C4H de Ruta graveolens (CYP73A32) au psoralène. Deux régions protéiques semblent impliquées dans l’inactivation différentielle entre CYP73A32 et CYP73A1. L’une, entre les résidus 31 et 58, est responsable de l’affinité pour le psoralène. L’autre, entre les résidus 229 et 379, contrôle la vitesse d’inactivation. La caractérisation de nouveaux P450 de la biosynthèse des furocoumarines a été entreprise. D’une part, plusieurs ADNc partiels ont été clonés chez Ruta graveolens. D’autre part, CYP71AJ1 isolé chez Ammi majus, a été caractérisé comme étant une psoralène synthase. La spécificité de CYP71AJ1 pour la marmésine a été approchée par l’étude d’un modèle 3D. Mots clés : cytochrome P450, psoralène synthase, cinnamate-4-Hydroxylase, C4H, métabolite secondaire, Ruta graveolens, Ammi majus, inactivation autocatalytique, furocoumarines, psoralène, (+)-marmésine, Modélisation 3D, (+)-columbianetine / Furocoumarins are phytoalexins known as efficient therapeutic agents. The work reported here focuses on cytochromes P450 involved in their biosynthesis pathway. A “structure-function” study was realized to understand how C4H from Ruta graveolens (CYP73A32) can resist to psoralen mechanism-based inactivation. Two parts of the protein seems involved in the differential susceptibility of CYP73A32 and CYP73A1 to psoralen. The first, between amino acids 31 and 58, defines differential affinity to psoralen. The second between residues 229 and 379 controls inactivation kinetic. The second part of this work was devoted to cloning and identification of new P450 involved in furocoumarin biosynthesis. On the one hand, several partial cDNA were cloned from Ruta graveolens. On the other hand, CYP71AJ1, cloned from Ammi majus, was identified as a psoralen synthase. The specificity of CYP71AJ1 for marmesin was approached by the study of a 3D model.
122

FTIR-spektroskopische Untersuchungen am Phytochrom Agp2

Piwowarski, Patrick 18 May 2017 (has links)
In der vorliegenden Arbeit wurde der lichtinduzierte Reaktionszyklus des bakteriellen Phytochroms Agp2 aus Agrobacterium tumefaciens mit FTIR‑ und UV‑Vis‑Spektroskopie untersucht. Der Photorezeptor besteht aus einem photosensorischen Modul und einer signalgebenden Histidin-Kinase-Domäne. Das photosensorische Modul bindet das Tetrapyrrol Biliverdin als Chromophor. Der Grundzustand von Agp2 (Pfr, 750 nm) ist gegenüber dem lichtaktivierten Zustand (Pr, 700 nm) rotverschoben, weshalb Agp2 den Bathyphytochromen zugeordnet wird. Die Untersuchungen erfolgten unter Verwendung von Isotopenmarkierung, H/D-Austauschexperimenten und ortsspezifischer Mutagenese. Daraus ließen sich folgende molekulare Änderungen charakterisieren, welche im Reaktionszyklus von Agp2 erfolgen: Die lichtinduzierte Isomerisierung des Chromophors führt zu einem Übergang vom Pfr- in den Pr-Zustand, wobei zwei Intermediate, Lumi‑F und Meta‑F, durchlaufen werden. Neben der Konformationsänderung des Chromophor‑D‑Rings ist auch die C‑Ring-Propionsäureseitenkette an der Photoreaktion beteiligt. Die C-Ring-Propionsäureseitenkette ist im Pfr-Zustand protoniert und wird im Übergang von Meta-F zu Pr deprotoniert. Der Pr-Zustand weist eine pH-Abhängigkeit auf, welche auf die pH-abhängige Ladung des Histidins 278 der Chromophortasche zurückzuführen ist. Je nach Ladung des Histidins 278 wird die Keto‑ bzw. Enolform der C(19)=O‑Gruppe des D‑Rings stabilisiert. Die Keto/Enol-Tautomerie ist auf eine innerhalb des Chromophors erfolgende Protontranslokation zurückzuführen und moduliert die Relaxation in den Pfr-Zustand. Änderungen der Amid-I-Absorption im Pfr-Pr-Übergang werden der Umstrukturierung der Tongue-Region des photosensorischen Moduls von einer Alpha-helikalen zu einer Beta‑Faltblatt-Struktur zugeordnet. Diese Strukturänderung wird als möglicher Weg der proteininternen Signaltransduktion zwischen photosensorischem und signalgebendem Modul vorgeschlagen. / In this thesis the light-induced reaction cycle of the bacterial phytochrome Agp2 from Agrobacterium tumefaciens was investigated using FTIR and UV‑vis spectroscopy. The photoreceptor comprises a photosensitive module and a signalling histidine kinase domain. The photosensitive module binds the biliverdin tetrapyrrol as chromophore. The Agp2 ground state (Pfr, 750 nm) is red-shifted in comparison with its light-activated state (Pr, 700 nm). Therefore, Agp2 is assigned to the group of bathy phytochromes. The investigations were conducted using isotopically labelled protein, labelled chromophore as well as hydrogen‑deuterium (H‑D) exchange and site-directed mutagenesis. Based on these the following molecular changes could be characterized that occur in the reaction cycle of Agp2: The light-induced isomerization of the chromophore leads to a transition from the Pfr to the Pr state, involving two intermediates, Lumi-F and Meta-F. Besides conformational changes of the chromophore D-ring, the C-ring propionic side chain is involved in the photoreaction as well. The C-ring propionic side chain is protonated in the Pfr state and gets deprotonated in the Meta-F to Pr transition. The Pr state exhibits pH‑dependent alterations which can be explained by pH dependent polarity changes of histidine 278 in the chromophore pocket. Depending on the charge of histidine, the D‑ring C(19)=O group is stabilized either in keto or enol form. The keto/enol tautomerism involves a proton translocation within the chromophore and modulates the relaxation to the Pfr state. The changes in the amide I region in the Pfr-Pr transition are associated with an alpha‑helix to beta‑sheet secondary structure change of the PHY domain tongue‑region. This structural change is proposed as the potential path of signal transduction between the photosensitive and the signalling module.
123

Mapeamento dos subsítios de α-amilase de Xanthomonas axonopodis pv citri envolvidos na interação com o substrato / Subsite mapping of Xanthomonas axonopodis pv citri α-amylase involved in substrate binding

Pinho, Jean Marcel Rodrigues 20 December 2004 (has links)
Mapeamento dos subsítios de α-amilase de Xanthomonas axonopodis pv. Citri envolvidos na interação com o substrato A família das enzimas α-amilases é um modelo experimental interessante para o estudo das interações entre os aminoácidos e seus ligantes, já que estas enzimas apresentam especificidade variável, são frequentemente alvos de estudos por mutagênese e há estruturas cristalinas disponíveis para alguns membros da família. A proposta deste trabalho foi o mapear subsítios da α-amilase de Xanthomonas axonopodis pv. citri (AXA) envolvidos na interação com substratos, através de comparações estruturais, mutagêneses sítio-dirigidas, análises de parâmetros cinéticos sobre amido e do padrão de clivagem sobre p-nitrofenil malto-oligossacarideos (PNPG7, PNPG5, PNPG4). Foi criado um modelo estrutural para AXA a partir da estrutura tridimensional da α-amilase de Alteromonas haloplanctis (Aghajari et al., 1998). O modelo de AXA foi sobreposto na estrutura da α-amilase pancreática de porco (Qian et al., 1994) e 11 resíduos foram selecionados e mutados para alanina. As α-amilases recombinantes mutantes e selvagem foram secretadas pela levedura Pichia pastoris GS115, apresentando uma massa molecular aparente de 45 kDa. Todos os mutantes analisados reduziram em maior ou menor grau a atividade catalítica da enzima sobre amido e p-nitrofenil maltooligossacarideos. Mutações dos resíduos H88, F136, D196, E223, D295 e N299, deletaram a atividade enzimática, indicando que suas cadeias laterais são essenciais para o desempenho catalítico da enzima. As análises cinéticas e estruturais sugerem fortemente que D196, E223 e D295 são os resíduos catalíticos. Substituições das cadeias laterais de C157, H200, G227, T230 e H294 reduziram a eficiência catalítica (kcat/Km) da α-amilase sobre o substrato amido para, respectivamente, 28%, 41%, 84%, 81% e 51%. As mutações em G227 e T230 foram menos importantes para a atividade da enzima e afinidade pelo amido, entretanto, estes resíduos mostraram-se importantes para a estabilização de complexos com substratos curtos (pNPG4). Os resultados indicam que o sítio ativo de AXA é formado por, no mínimo, seis subsítios. As interações dos anéis de glicose com os subsítios +2 e -2 são favorecidas em relação às interações nos subsítios -3 e +3, respectivamente, e a interação do anel de glicose no subsítio -3 é favorecida em relação à interação no subsítio +3. A enzima selvagem diva preferencialmente a terceira ligação glicosídica de p-nitrofenil maltooligossacarideos. Como produtos de hidrólise a enzima libera maltopentaose, maltotetraose, maltotriose, maltose e glicose. / The α-amylase family is an interesting group for structure/function relationship investigation, as this family exhibits a variable deavage patterm, several crystal structures are available, and its members were studied by mutagenesis. The aim of this study was the mapping of Xanthomonas axonopodis pv. Citri α-amylase (AXA) subsites involved in substrate binding, using structural comparison, site-directed mutagenesis and lcinetics analyses. A structural model for AXA was created from the three-dimensional structure of the α-amylase from Alteromonas haloplanctis (Aghajari et al., 1998). This model was superimposed on the structure ofthe pig pancreatic α-amylase, PPA (Qian et. al., 1994), and 11 residues were selected and changed to alanine. Wild type and mutant AXA were secreted by Pichia pastoris strain GS115 cells and showed apparent molecular mass of 45 kDa. All mutants have reduced α-amylase activity on starch and 4-nitrophenyl maltooligosaccharides (pNPG7, PNPG5 and PNPG4) at different levels. Mutation of residues H88, F136, D196, E223, D295 and N299 indicate their essential role by complete loss of activity. Kinetic and structural analyses strongly suggested that D196, E223 and D295 are the catalytic residues. The substitution of the side chain of C157, H200, G227, T230 and H294 reduced the catalytic efficiency (kcat/Km) of α-amylase on starch to respectively 28%, 41%, 84%, 81% and 51%. Although G227 and T230 were not much important for activity and binding on starch, these residues were important for stabilization of complexes with short substrates (PNPG4). The results indicate that AXA\'s active site is composed of at least six sugar binding subsites. The binding of the glucoses at subsites +2 and -2 are favored against binding at subsites -3 and +3, respectively. The binding of glucose at subsite -3 is favored against binding at subsite +3. The wild type enzyme primarily hydrolyzes the third glucosidic bond in PNPG7, PNPG5 and PNPG4 and the products of hydrolysis were maltopentaose, maltotetraose, maltotriose, maltose and glucose.
124

Mutational Analysis and Redesign of Alpha-class Glutathione Transferases for Enhanced Azathioprine Activity

Modén, Olof January 2013 (has links)
Glutathione transferase (GST) A2-2 is the human enzyme most efficient in catalyzing azathioprine activation. Structure-function relationships were sought explaining the higher catalytic efficiency compared to other alpha class GSTs. By screening a DNA shuffling library, five recombined segments were identified that were conserved among the most active mutants. Mutational analysis confirmed the importance of these short segments as their insertion into low-active GSTs introduced higher azathioprine activity. Besides, H-site mutagenesis led to decreased azathioprine activity when the targeted positions belonged to these conserved segments and mainly enhanced activity when other positions were targeted. Hydrophobic residues were preferred in positions 208 and 213. The prodrug azathioprine is today primarily used for maintaining remission in inflammatory bowel disease. Therapy leads to adverse effects for 30 % of the patients and genotyping of the metabolic genes involved can explain some of these incidences. Five genotypes of human A2-2 were characterized and variant A2*E had 3–4-fold higher catalytic efficiency with azathioprine, due to a proline mutated close to the H-site. Faster activation might lead to different metabolite distributions and possibly more adverse effects. Genotyping of GSTs is recommended for further studies. Molecular docking of azathioprine into a modeled structure of A2*E suggested three positions for mutagenesis. The most active mutants had small or polar residues in the mutated positions. Mutant L107G/L108D/F222H displayed a 70-fold improved catalytic efficiency with azathioprine. Determination of its structure by X-ray crystallography showed a widened H-site, suggesting that the transition state could be accommodated in a mode better suited for catalysis. The mutational analysis increased our understanding of the azathioprine activation in alpha class GSTs and highlighted A2*E as one factor possibly behind the adverse drug-effects. A successfully redesigned GST, with 200-fold enhanced catalytic efficiency towards azathioprine compared to the starting point A2*C, might find use in targeted enzyme-prodrug therapies.
125

Expression of human α-N-Acetylglucosaminidase in Sf9 insect cells: effect of cryptic splice site removal and native secretion-signaling peptide addition.

Jantzen, Roni Rebecca 15 August 2011 (has links)
Human α-N-Acetylglucosaminidase (Naglu) is a lysosomal acid hydrolase implicated in tthe rare metabolic storage disorder known as mucopolysaccharidosis type IIIB (MPS IIIB; also Sanfilippo syndrome B). Absence of this enzyme results in cytotoxic accumulation of heparan sulphate in the central nervous system, causing mental retardation and a shortened lifespan. Enzyme replacement therapy is not currently effective to treat neurological symptoms due to the inability of exogenous Naglu to access the brain. This laboratory uses a Spodoptera frugiperda (Sf9) insect cell system to express Naglu fused to a synthetic protein transduction domain with the intent to facilitate delivery of Naglu across the blood-brain barrier. The project described herein may be broken down into three main sections. Firstly, the impact of two cryptic splice sites on Naglu expression levels was analyzed in both transiently expressing Sf9 cultures and stably selected cell lines. Secondly, the effectiveness of the native Naglu secretion-signaling peptide in the Sf9 system was examined. Finally, purification of a Naglu fusion protein from suspension culture medium was performed using hydrophobic interaction chromatographic techniques. The ultimate goal of this research is to develop an efficient system for economical, large-scale production of a human recombinant Naglu fusion protein that has the potential to be successfully used for enzyme replacement therapy to treat MPS IIIB. / Graduate
126

Mapeamento dos subsítios de α-amilase de Xanthomonas axonopodis pv citri envolvidos na interação com o substrato / Subsite mapping of Xanthomonas axonopodis pv citri α-amylase involved in substrate binding

Jean Marcel Rodrigues Pinho 20 December 2004 (has links)
Mapeamento dos subsítios de α-amilase de Xanthomonas axonopodis pv. Citri envolvidos na interação com o substrato A família das enzimas α-amilases é um modelo experimental interessante para o estudo das interações entre os aminoácidos e seus ligantes, já que estas enzimas apresentam especificidade variável, são frequentemente alvos de estudos por mutagênese e há estruturas cristalinas disponíveis para alguns membros da família. A proposta deste trabalho foi o mapear subsítios da α-amilase de Xanthomonas axonopodis pv. citri (AXA) envolvidos na interação com substratos, através de comparações estruturais, mutagêneses sítio-dirigidas, análises de parâmetros cinéticos sobre amido e do padrão de clivagem sobre p-nitrofenil malto-oligossacarideos (PNPG7, PNPG5, PNPG4). Foi criado um modelo estrutural para AXA a partir da estrutura tridimensional da α-amilase de Alteromonas haloplanctis (Aghajari et al., 1998). O modelo de AXA foi sobreposto na estrutura da α-amilase pancreática de porco (Qian et al., 1994) e 11 resíduos foram selecionados e mutados para alanina. As α-amilases recombinantes mutantes e selvagem foram secretadas pela levedura Pichia pastoris GS115, apresentando uma massa molecular aparente de 45 kDa. Todos os mutantes analisados reduziram em maior ou menor grau a atividade catalítica da enzima sobre amido e p-nitrofenil maltooligossacarideos. Mutações dos resíduos H88, F136, D196, E223, D295 e N299, deletaram a atividade enzimática, indicando que suas cadeias laterais são essenciais para o desempenho catalítico da enzima. As análises cinéticas e estruturais sugerem fortemente que D196, E223 e D295 são os resíduos catalíticos. Substituições das cadeias laterais de C157, H200, G227, T230 e H294 reduziram a eficiência catalítica (kcat/Km) da α-amilase sobre o substrato amido para, respectivamente, 28%, 41%, 84%, 81% e 51%. As mutações em G227 e T230 foram menos importantes para a atividade da enzima e afinidade pelo amido, entretanto, estes resíduos mostraram-se importantes para a estabilização de complexos com substratos curtos (pNPG4). Os resultados indicam que o sítio ativo de AXA é formado por, no mínimo, seis subsítios. As interações dos anéis de glicose com os subsítios +2 e -2 são favorecidas em relação às interações nos subsítios -3 e +3, respectivamente, e a interação do anel de glicose no subsítio -3 é favorecida em relação à interação no subsítio +3. A enzima selvagem diva preferencialmente a terceira ligação glicosídica de p-nitrofenil maltooligossacarideos. Como produtos de hidrólise a enzima libera maltopentaose, maltotetraose, maltotriose, maltose e glicose. / The α-amylase family is an interesting group for structure/function relationship investigation, as this family exhibits a variable deavage patterm, several crystal structures are available, and its members were studied by mutagenesis. The aim of this study was the mapping of Xanthomonas axonopodis pv. Citri α-amylase (AXA) subsites involved in substrate binding, using structural comparison, site-directed mutagenesis and lcinetics analyses. A structural model for AXA was created from the three-dimensional structure of the α-amylase from Alteromonas haloplanctis (Aghajari et al., 1998). This model was superimposed on the structure ofthe pig pancreatic α-amylase, PPA (Qian et. al., 1994), and 11 residues were selected and changed to alanine. Wild type and mutant AXA were secreted by Pichia pastoris strain GS115 cells and showed apparent molecular mass of 45 kDa. All mutants have reduced α-amylase activity on starch and 4-nitrophenyl maltooligosaccharides (pNPG7, PNPG5 and PNPG4) at different levels. Mutation of residues H88, F136, D196, E223, D295 and N299 indicate their essential role by complete loss of activity. Kinetic and structural analyses strongly suggested that D196, E223 and D295 are the catalytic residues. The substitution of the side chain of C157, H200, G227, T230 and H294 reduced the catalytic efficiency (kcat/Km) of α-amylase on starch to respectively 28%, 41%, 84%, 81% and 51%. Although G227 and T230 were not much important for activity and binding on starch, these residues were important for stabilization of complexes with short substrates (PNPG4). The results indicate that AXA\'s active site is composed of at least six sugar binding subsites. The binding of the glucoses at subsites +2 and -2 are favored against binding at subsites -3 and +3, respectively. The binding of glucose at subsite -3 is favored against binding at subsite +3. The wild type enzyme primarily hydrolyzes the third glucosidic bond in PNPG7, PNPG5 and PNPG4 and the products of hydrolysis were maltopentaose, maltotetraose, maltotriose, maltose and glucose.
127

Nouveaux concepts dans la pharmacologie des récepteurs aux acides gras à chaîne courte FFA2 et FFA3 / New insights into the pharmacology of the short-chain free fatty acid receptors 2 and 3

Moussaud, Elisabeth 10 June 2011 (has links)
Les maladies métaboliques, comme le diabète, la dyslipidémie ou l’obésité, constituent un problème majeur de santé publique dans les pays développés. Ces maladies très répandues restent encore difficiles à traiter malgré une recherche active. Les stratégies thérapeutiques contre ces maladies incluent le développement de nouvelles molécules ciblant les récepteurs aux acides gras, étant donné leur rôle essentiel dans l’homéostasie du métabolisme. C’est dans ce contexte que s’inscrit ce travail portant sur deux récepteurs couplés aux protéines G, les récepteurs aux acides gras à courte chaîne 2 et 3 ou free fatty acid receptors 2 (FFA2) et 3 (FFA3). Nous avons tout d'abord cherché à déterminer le profil d'expression des deux récepteurs. Ensuite, nous avons établi des lignées cellulaires stable exprimant FFA2 ou FFA3 afin d’étudier la pharmacologie d’agonistes synthétiques et endogènes de ces récepteurs. Après avoir identifié les voies de signalisation engendrées par l’activation des récepteurs, nous avons démontré que les agonistes synthétiques étaient des activateurs allostériques, c’est-à-dire qu’ils se liaient aux récepteurs sur un site distinct de celui des ligands endogènes. Pour identifier les résidus d’acides aminés nécessaires à la reconnaissance des ligands, nous avons généré une gamme de mutants ponctuels de ces récepteurs par mutagénèse dirigée. En analysant l’effet des mutations dans des tests fonctionnels, nous avons pu déterminer avec précision où se liaient les ligands et ainsi pu dessiner par informatique des modèles structuraux des récepteurs qui pourront être utilisés pour le drug design de futures molécules agonistes de ces récepteurs. / Metabolic diseases, such as diabetes, dyslipidemia or obesity, are more and more weighing on public health expenses in developed countries. Despite active research, these widespread diseases remain difficult to handle. Promising new therapeutic strategies against metabolic diseases include the development of drugs targeting the free fatty acid receptors, as key players in metabolism homeostasis. In this context, the current PhD thesis focuses on the study of two G protein-coupled receptors, namely the short-chain free fatty acid receptors 2 (FFA2) and 3 (FFA3). First, we investigated the expression of the two receptors of interest in a variety of cell types. Then, in order to study the pharmacology and the binding mode of endogenous and synthetic agonists on FFA2 and FFA3, we established stable cell lines expressing each receptor. Once we identified the signaling pathways engendered in response to receptor activation, we showed that synthetic agonists were allosteric activators of the receptors, in the sense that they bind to the receptors at a distinct site from short-chain fatty acids, i.e. the endogenous agonists. To identify the aminoacid residues that were involved in ligand binding, we generated a variety of point mutated receptors by site-directed mutagenesis. By analyzing the effects of the mutations in functional tests, we determined precisely the aminoacid residues that were essential for ligand binding. From these results, we designed in silico structural models which may aid future drug design efforts for the discovery of new FFA2 and FFA3 agonists.
128

USING RECOMBINANT HUMAN CARBAMOYL PHOSPHATE SYNTHETASE 1 (CPS1) FOR STUDYING THIS ENZYME'S FUNCTION, REGULATION, PATHOLOGY AND STRUCTURE

Díez Fernández, Carmen 09 July 2015 (has links)
Tesis por compendio / [EN] Carbamoyl phosphate synthetase 1 (CPS1), a 1462-residue mitochondrial enzyme, catalyzes the entry of ammonia into the urea cycle, which converts ammonia, the neurotoxic waste product of protein catabolism, into barely toxic urea. The urea cycle inborn error and rare disease CPS1 deficiency (CPS1D) is inherited with mendelian autosomal recessive inheritance, being due to CPS1 gene mutations (>200 mutations reported), and causing life-threatening hyperammonemia. We have produced recombinantly human CPS1 (hCPS1) in a baculovirus/insect cell expression system, isolating the enzyme in active and highly purified form, in massive amounts. This has allowed enzyme crystallization for structural studies by X-ray diffraction (an off-shoot of the present studies). This hCPS1 production system allows site-directed mutagenesis and enzyme characterization as catalyst (activity, kinetics) and as protein (stability, aggregation state, domain composition). We have revealed previously unexplored traits of hCPS1 such as its domain composition, the ability of glycerol to replace the natural and essential CPS1 activator N-acetyl-L-glutamate (NAG), and the hCPS1 protection (chemical chaperoning) by NAG and by its pharmacological analog N-carbamyl-L-glutamate (NCG). We have exploited this system to explore the effects on the activity, kinetic parameters and stability/folding of the enzyme, and to test the disease-causing nature, of mutations identified in patients with CPS1 deficiency (CPS1D). These results, supplemented with those obtained with other non-clinical mutations, have provided novel information on the functions of three non-catalytic domains of CPS1. We have introduced three CPS1D-associated mutations and one trivial polymorphism in the glutaminase-like domain of CPS1, supporting a stabilizing and an activity-enhancing function of this non-catalytic domain. Two mutations introduced into the bicarbonate phosphorylation domain have shed light on bicarbonate binding and have directly confirmed the importance of this domain for NAG binding to the distant (in the sequence) C-terminal CPS1 domain. The introduction of 18 CPS1D-associated missense mutations mapping in a clinically highly eloquent central non-catalytic domain have proven the disease-causing nature of most of these mutations while showing that in most of the cases they trigger enzyme misfolding and/or destabilization. These results, by proving an important role of this domain in the structural integration of the multidomain CPS1 protein, have led us to call this domain the Integrating Domain. Finally, we have examined the effects of eight CPS1D-associated mutations, of one trivial polymorphism and of five non-clinical mutations, all of them mapping in the C-terminal domain of the enzyme where NAG binds, whereas we have re-analyzed prior results with another four clinical and five non-clinical mutations affecting this domain. We have largely confirmed the pathogenic nature of the clinical mutations, predominantly because of decreased activity, in many cases due to hampered NAG binding. A few mutations had substantial negative effects on CPS1 stability/folding. Our analysis reveals that NAG activation begins with a movement of the final part of the ß4-¿4 loop of the NAG site. Transmission of the activating signal to the phosphorylation domains involves helix ¿4 from this domain and is possibly transmitted by the mutually homologous loops 1313-1332 and 778-787 (figures are residue numbers) belonging, respectively, to the carbamate and bicarbonate phosphorylation domains. These two homologous loops are called from here on Signal Transmission Loops. / [ES] La carbamil fosfato sintetasa 1 (CPS1), una enzima mitocondrial, cataliza la entrada del amonio en el ciclo de la urea, que convierte esta neurotoxina derivada del catabolismo de las proteínas en urea, mucho menos tóxica. El déficit de CPS1 (CPS1D) es un error innato del ciclo de la urea, una enfermedad rara autosómica recesiva, que se debe a mutaciones en el gen CPS1 (>200 mutaciones descritas) y que cursa con hiperamonemia. Hemos producido CPS1 humana recombinante (hCPS1) en un sistema de expresión de células de insecto y baculovirus, y la hemos aislado en forma activa, muy pura y en cantidad elevada. Este sistema de producción de hCPS1 permite la realización de mutagénesis dirigida y la caracterización de la enzima como catalizador (actividad, cinética) y como proteína (estabilidad, estado de agregación y composición de dominios). Hemos revelado características de la hCPS1 antes no exploradas como es la composición de dominios, la capacidad que tiene el glicerol para reemplazar al activador natural y esencial de la CPS1, N-acetil-L-glutamato (NAG), y la protección de la hCPS1 por NAG y por su análogo farmacológico N-carbamil-L-glutamato (NCG) (chaperonas químicas). Hemos utilizado este sistema para explorar los efectos en actividad, parámetros cinéticos y estabilidad/plegamiento de la enzima, y para comprobar la naturaleza patogénica de mutaciones identificadas en pacientes con CPS1D. Estos resultados, junto con los obtenidos con otras mutaciones no clínicas, han aportado información novedosa sobre tres de los dominios no catalíticos de CPS1. Las observaciones realizadas tras introducir en el dominio de tipo glutaminasa de la enzima tres mutaciones asociadas a CPS1D y un polimorfismo trivial, apoyan la contribución de este dominio no catalítico a la estabilidad y a aumentar la actividad de la enzima. Dos mutaciones introducidas en el dominio de fosforilación de bicarbonato han arrojado luz sobre el modo de unión del bicarbonato (un sustrato). Los resultados de estas mutaciones también han confirmado la contribución de este dominio para la unión de NAG, cuyo sitio de unión se encuentra en el dominio C-terminal de CPS1, bastante alejado (en la secuencia) del dominio de fosforilación de bicarbonato. Además, hemos introducido 18 mutaciones de cambio de sentido asociadas a CPS1D, las cuales están localizadas en un dominio no catalítico, central y de elevada elocuencia clínica. Estos resultados han demostrado la naturaleza patogénica de estas mutaciones, ya que en la mayoría de los casos estas mutaciones producen un mal plegamiento o/y desestabilización de la enzima. Debido a que estos resultados han puesto de manifiesto el importante papel de este dominio en la integración estructural de la proteína multidominio CPS1, lo hemos llamado Dominio Integrador. Finalmente, hemos examinado los efectos de 8 mutaciones asociadas a CPS1D, de un polimorfismo trivial y de 5 mutaciones no clínicas, todas localizadas en el dominio C-terminal de la enzima, donde se une NAG. Además, hemos reanalizado resultados anteriores con otras 4 mutaciones clínicas y 5 no clínicas afectando a este dominio. Hemos confirmado el carácter patogénico de las mutaciones clínicas, las cuales predominantemente causan una disminución en la actividad enzimática, en muchos casos debida a que la unión de NAG se encuentra obstaculizada. Unas pocas mutaciones mostraron efectos negativos en la estabilidad/plegamiento de CPS1. Nuestros análisis revelan que la activación por el NAG empieza con un movimiento de la parte final del bucle ß4-¿4 del sitio de NAG. La transmisión de la señal activadora a los dominios de fosforilación implica a la hélice ¿4 de este dominio y posiblemente se transmite a través de los bucles homólogos 1313-1332 y 778-787 (numeración de residuos) pertenecientes, respectivamente, a los dominios de fosforilación de carbamato y bicarbonato. Por ello, hemos llamado a ambos bucles Bucles de / [CA] La carbamil fosfat sintetasa 1 (CPS1), un enzim mitocondrial, catalitza l'entrada d'amoni en el cicle de la urea, que convertix l'amoni, producte neurotòxic del catabolisme de les proteïnes, en urea, una molècula molt poc tòxica. El dèficit de CPS1 (CPS1D) és un error innat del cicle de la urea, una malaltia rara autosòmica recessiva, que es deu a mutacions en el gen CPS1 (>200 mutacions descrites) i que cursa amb hiperamonièmia. Hem produït CPS1 humana recombinant (hCPS1) en un sistema d'expressió de cèl·lules d'insecte i baculovirus, i l'hem aïllada en forma activa, molt pura i en gran quantitat. Això ha permés la cristal·lització de l'enzim per a estudis estructurals amb difracció de raios-X (treball no inclòs en esta tesi Aquest sistema de producció de hCPS1 permet la realització de mutagènesi dirigida i la caracterització de l'enzim com a catalitzador (activitat, cinètica) i com a proteïna (estabilitat, estat d'agregació i composició de dominis). Hem revelat característiques de la hCPS1 no explorades abans com és la composició de dominis, la capacitat que té el glicerol per a reemplaçar l'activador natural i essencial de CPS1, N-acetil-L-glutamat (NAG), i la protecció de la hCPS1 per NAG i pel seu anàleg farmacològic N-carbamil-L-glutamat (NCG) (xaperones químiques) . Hem utilitzat aquest sistema per a explorar els efectes en l'activitat, els paràmetres cinètics i l'estabilitat/plegament de l'enzim, i per a comprovar la naturalesa patogènica de mutacions identificades en pacients amb CPS1D. Aquestos resultats, junt amb els obtinguts amb altres mutacions no clíniques, han aportat informació nova sobre tres dels dominis no catalítics de la CPS1. Les observacions, després d'introduir tres mutacions associades a CPS1D i un polimorfisme trivial en el domini tipus glutaminasa de CPS1, recolzen la contribució d'aquest domini no catalític a l'estabilitat i a l'optimització de l'activitat enzimàtica. Dues mutacions introduïdes en el domini de fosforilació de bicarbonat han esclarit el mode d'unió de bicarbonat. Els resultats d'aquestes mutacions també han confirmat la contribució d'aquest domini per a la unió de NAG, el lloc d'unió de la qual es troba en el domini C-terminal de CPS1, prou allunyat (en la seqüència) del domini de fosforilació de bicarbonat. A més, hem introduït 18 mutacions de canvi de sentit associades a CPS1D, les quals estan localitzades en un domini no catalític, central i d'elevada eloqüència clínica. Aquestos resultats han demostrat la naturalesa patogènica d'aquestes mutacions, ja que, en la majoria dels casos produïxen un mal plegament o/i desestabilització de l'enzim. Pel fet que aquestos resultats han posat de manifest l'important paper d'aquest domini en la integració estructural de la proteïna multidomini CPS1, l'hem anomenat Domini Integrador. Finalment, hem examinat els efectes de huit mutacions associades a CPS1D, un polimorfisme trivial i cinc mutacions no clíniques, totes elles localitzades en el domini C-terminal de l'enzim, on s'unix NAG. A més, hem reanalitzat resultats anteriors amb altres quatre mutacions clíniques i cinc no clíniques que afecten aquest domini. Hem confirmat el caràcter patogènic de les mutacions clíniques, les quals predominantment causen una disminució en l'activitat enzimàtica, en molts casos pel fet que la unió de NAG es troba obstaculitzada. Unes poques mutacions van mostrar efectes negatius substancials en l'estabilitat/plegament de CPS1. Les nostres anàlisis revelen que l'activació de NAG comença amb un moviment de la part final del bucle ß4-¿4 del lloc de NAG. La transmissió del senyal activadora als dominis de fosforilació involucra l'hèlix ¿4 d'aquest domini i es transmet, possiblement, a través dels bucles homòlegs 1313-1332 i 778-787 (numeració dels residus), pertanyents, respectivament, als dominis de fosforilació de carbamato i bicarbonat. Per això, hem anomenat a ambd / Díez Fernández, C. (2015). USING RECOMBINANT HUMAN CARBAMOYL PHOSPHATE SYNTHETASE 1 (CPS1) FOR STUDYING THIS ENZYME'S FUNCTION, REGULATION, PATHOLOGY AND STRUCTURE [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/52855 / Compendio
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Études structure-fonction par modélisation moléculaire et mutagénèse dirigée de cibles thérapeutiques potentielles impliquées dans la régulation de l'équilibre hydrique et des fonctions cardiovasculaires / Structure-function studies by molecular modeling and site-directed mutagenesis of potential therapeutic targets involved in the regulation of body fluid homeostasis and cardiovascular functions.

Couvineau, Pierre 29 June 2017 (has links)
Ces travaux de thèse s'articulent autour de deux projets : les études structure-fonction de l'aminopeptidase A, d'une part, et celles du récepteur de l'apéline, d'autre part. I/ L'aminopeptidase A (APA, EC 3.4.11.7) est une aminopeptidase monozinc membranaire qui, dans le cerveau, produit l'angiotensine (Ang) III à partir de l'Ang II. L'Ang III est l'un des principaux peptides effecteurs du système rénine-angiotensine cérébral qui exerce un effet stimulateur tonique sur le contrôle central de la pression artérielle chez le rat hypertendu. Ainsi le blocage de l'APA par un inhibiteur spécifique et sélectif, l'EC33 ou sa prodrogue, le RB150, normalise la pression artérielle dans deux modèles expérimentaux d'hypertension artérielle (HTA). L'APA constitue une cible thérapeutique potentielle pour le traitement de l'HTA qui justifie le développement de nouveaux inhibiteurs de cette enzyme plus puissants et plus sélectifs que l'EC33 et avec un profil pharmacodynamique et pharmacocinétique amélioré par rapport au RB150. Pour cela, nous avons construit un modèle tridimensionnel (3D) de l'APA sur la base de la structure cristallographique de l'APA humaine récemment publiée. Nous avons ensuite validé ce modèle par des études structure-fonction par modélisation moléculaire et mutagénèse dirigée en démontrant l'implication, d'un résidu du sous-site S1 dans la spécificité de substrat acide de l'APA et de deux résidus formant le sous-site S2' interagissant avec le résidu P2' acide d'inhibiteurs tripeptidiques précédemment développés dans le laboratoire.II/ L'apéline est le ligand naturel du récepteur orphelin humain APJ (ApélineR), un récepteur à sept domaines transmembranaires couplé aux protéines G. L'apéline et son récepteur sont impliqués dans le maintien de l'équilibre hydrique et des fonctions cardiovasculaires. L'ApélineR constitue une cible thérapeutique potentielle dans le traitement de l'insuffisance cardiaque et des rétentions hydriques. Etant donné que la demi-vie de l'apéline dans la circulation sanguine est de l'ordre de la minute, l'objectif est de développer des analogues de l'apéline métaboliquement stables. Pour développer de tels composés, nous avons entrepris de comprendre comment l'apéline se lie à son récepteur et comment elle l'active. Dans ce but, nous avons construit un modèle 3D de l'ApélineR basé sur la structure cristallographique du récepteur aux chimiokines, CXCR4. Nous avons validé ce modèle par des études structure-fonction par modélisation moléculaire et mutagénèse dirigée. Nous avons identifié à la surface du récepteur, les résidus acides des boucles extracellulaires qui interagissent avec les résidus basiques de l'apéline. Nous avons ensuite développé des analogues de l'apéline-17 (K17F) métaboliquement stables par deux stratégies différentes. Premièrement, nous avons substitué chacun des résidus de l'apéline par son énantiomère de la série D ou par un acide aminé synthétique. Deuxièmement, nous avons ajouté une chaîne fluoroalkyle à l'extrémité N-terminale de l'apéline. Ces deux stratégies ont permis d'obtenir plusieurs composés dont les plus actifs sont le P92 et le LIT01-196 qui conservent des propriétés pharmacologiques identiques à celles de K17F et qui présentent une demi-vie plasmatique largement supérieure à celle du peptide endogène. Ces deux analogues se sont révélés particulièrement actifs in vivo avec une capacité à diminuer la pression artérielle et à réduire la sécrétion de vasopressine dans le sang conduisant à une augmentation de la diurèse aqueuse. Les modèles 3D validés de l'APA et de l'ApélineR seront utilisés pour des campagnes de criblage in silico de chimiothèques virtuelles afin de découvrir de nouveaux inhibiteurs de l'APA et des agonistes de l'ApélineR qui pourraient conduire à terme à de nouveaux candidats-médicaments. Ces composés pourraient être utiles pour le traitement de l'HTA et de l'insuffisance cardiaque. / The doctoral work was divided in two parts, one on the structure-function studies of aminopeptidase A, and the second one, on those of the apelin receptor. I/ Aminopeptidase A (APA) is a membrane bound monozinc aminopeptidase which generates, in the brain, angiotensin (Ang) III from Ang II. Ang III is one of the main effector peptides of the brain renin-angiotensin system, which exerts a tonic stimulatory action on the control of blood pressure in hypertensive rats. Thus, the blockade of brain APA by a specific and selective inhibitor, EC33 or its prodrug, RB150, normalizes blood pressure in two animal models of arterial hypertension (HTA). APA constitutes a potential therapeutic target for the treatment of HTA that justifies the development of more potent and selective APA inhibitors than EC33, with enhanced pharmacodynamic and pharmacokinetic profiles when compared to RB150. With this aim, we built a three dimensional (3D) model of APA based on the recently published crystal structure of human APA. We validated this model by structure-function studies combining molecular modeling and site-directed mutagenesis demonstrating the crucial role of one residue in the S1 subsite responsible for substrate specificity of APA for N-terminal acidic amino-acid residues and two other residues constituting the S2' subsite of APA involved in the binding of the P2' acidic residue of tripeptidic inhibitors, previously developed in the laboratory. II/ Apelin is the endogenous ligand of the human orphan receptor named APJ (ApelinR), a G protein-coupled receptor. Apelin and ApelinR are involved in the control of body fluid homeostasis and cardiovascular functions. ApelinR constitutes a potential therapeutic target for the treatment of heart failure and water retentions. Given that apelin half-life in the blood circulation is in the minute range, we aimed to develop potent metabolically stable apelin analogs.. In this context, it is necessary to understand how apelin binds to ApelinR and how it is activated. To do so, we build a 3D model of ApelinR based on the crystal structure of the chemokine receptor, CXCR4. We validated this model by structure-function studies by molecular modeling and site-directed mutagenesis. We showed that apelin interacts with the receptor through interactions between the basic residues of the peptide and the acidic residues of the ApelinR, located in the extracellular loops. ,We then developed metabolically stable apelin-17 (K17F) analogs following two different strategies. First, we substituted each residue of K17F by its D-isomer or a synthetic amino-acid. Secondly, we added a fluoroalkyl chain at the N-terminal part of K17F. These two strategies allowed to significantly improve plasma half-life of the modified peptides for several hours without modifying their pharmacological properties as compared to K17F. Two apelin metabolically stable analogs, P92 and LIT01-196, were found to have significantly higher in vivo activity than K17F with a strong capacity to decrease blood pressure and to inhibit vasopressin release in the blood stream inducing an increased aqueous diuresis. These new validated 3D models will be now used to perform in silico screening of virtual chemical libraries to discover new APA inhibitors and ApelinR agonists that could ultimately lead to new drug candidates. These compounds could be useful for the treatment of HTA and heart failure.
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Structural and Functional Characterization of O-Antigen Translocation and Polymerization in Pseudomonas aeruginosa PAO1

Islam, Salim Timo 07 June 2013 (has links)
Heteropolymeric O antigen (O-Ag)-capped lipopolysaccharide is the principal constituent of the Gram-negative bacterial cell surface. It is assembled via the integral inner membrane (IM) Wzx/Wzy-dependent pathway. In Pseudomonas aeruginosa, Wzx translocates lipid-linked anionic O-Ag subunits from the cytoplasmic to the periplasmic leaflets of the IM, where Wzy polymerizes the subunits to lengths regulated by Wzz1/2. The Wzx and Wzy IM topologies were mapped using random C-terminal-truncation fusions to PhoALacZα, which displays PhoA/LacZ activity dependent upon its subcellular localization. Twelve transmembrane segments (TMS) containing charged residues were identified for Wzx. Fourteen TMS, two sizeable cytoplasmic loops (CL), and two large periplasmic loops (PL3 and PL5 of comparable size) were characterized for Wzy. Despite Wzy PL3–PL5 sequence homology, these loops were distinguished by respective cationic and anionic charge properties. Site-directed mutagenesis identified functionally-essential Arg residues in both loops. These results led to the proposition of a “catch-and-release” mechanism for Wzy function. The abovementioned Arg residues and intra-Wzy PL3–PL5 sequence homology were conserved among phylogenetically diverse Wzy homologues, indicating widespread potential for the proposed mechanism. Unexpectedly, Wzy CL6 mutations disrupted Wzz1-mediated regulation of shorter O-Ag chains, providing the first evidence for direct Wzy–Wzz interaction. Mutagenesis studies identified functionally-important charged and aromatic TMS residues localized to either the interior vestibule or TMS bundles in a 3D homology model constructed for Wzx. Substrate-binding or energy-coupling roles were proposed for these residues, respectively. The Wzx interior was found to be cationic, consistent with translocation of anionic O-Ag subunits. To test these hypotheses, Wzx was overexpressed, purified, and reconstituted in proteoliposomes loaded with I−. Common transport coupling ions were introduced to “open” the protein and allow detection of I− flux via reconstituted Wzx. Extraliposomal changes in H+ induced I− flux, while Na+ addition had no effect, suggesting H+-dependent Wzx gating. Putative energy-coupling residue mutants demonstrated defective H+-dependent halide flux. Wzx also mediated H+ uptake as detected through fluorescence shifts from proteoliposomes loaded with pH-sensitive dye. Consequently, Wzx was proposed to function via H+-coupled antiport. In summary, this research has contributed structural and functional knowledge leading to novel mechanistic understandings for O-Ag biosynthesis in bacteria. / Bookmarks within the document have been provided for ease of access to a particular section in the body of the thesis. Each entry in the Table of Contents, List of Tables, and List of Figures has been "linked" to its respective position and as such can be clicked for direct access to the entry. Similarly, each in-text Figure or Table reference has been "linked" to its respective figure/table for direct access to the entry. / 1.) Canadian Institutes of Health Research (CIHR) Frederick Banting and Charles Best Canada Graduate Scholarship doctoral award, 2.) CIHR Michael Smith Foreign Study Award, 3.) Cystic Fibrosis Canada (CFC) doctoral studentship, 4.) University of Guelph Dean's Tri-Council Scholarship, 5.) Ontario Graduate Scholarship in Science and Technology, 6.) Operating grants to Dr. Joseph S. Lam from CIHR (MOP-14687) and CFC

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