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Interactions entre une biomolécule et son environnement : de la dynamique d'hydratation à la catalyse enzymatique / Interplay between a biomolecule and its environment : from hydration dynamics to enzyme catalysisDuboué-Dijon, Elise 14 September 2015 (has links)
Les biomolécules sont naturellement immergées dans l’eau, qui joue un rôle clé dans de nombreux processus biologiques. Réciproquement, les propriétés de l’eau sont affectées par la présence de la biomolécule. Dans cette thèse, nous combinons modèles théoriques et simulations numériques pour obtenir une description à l’échelle moléculaire des interactions entre une biomolécule et son environnement. Le manuscrit est structuré en deux parties, abordant deux aspects complémentaires de cette interaction complexe. La première partie est consacrée à la perturbation induite par une biomolécule sur l’eau. Nous déterminons en quoi la couche d’hydratation diffère de l’eau bulk et identifions les facteurs moléculaires en jeu. Nous comparons ensuite les couches d’hydratation d’une protéine antigel et d’une protéine modèle afin de déterminer si les propriétés d’hydratation peuvent expliquer l’activité antigel. Nous étudions enfin la dynamique d’hydratation de l’ADN. Nous obtenons une image résolue spatialement des propriétés de sa couche d’hydratation et y caractérisons les différentes sources d’hétérogénéité. La deuxième partie s’intéresse au rôle de l’environnement sur la catalyse enzymatique. Nous étudions deux systèmes distincts, avec des questions différentes mais une même méthodologie. Nous examinons d’abord le rôle de résidus dans le site actif de la dihydrofolate réductase et obtenons une interprétation moléculaire de résultats expérimentaux récents. Enfin, nous nous intéressons à la catalyse enzymatique en solvant organique, où l’addition de petites quantités d’eau permet d’accélérer la réaction. Nous recherchons une description à l’échelle moléculaire de cet effet. / Biomolecules are immersed in an aqueous solvent, which plays a key role in a wide range of biochemical processes. In addition, the properties of water molecules in the hydration shell are perturbed by the presence of the biomolecule. In this thesis, we combine theoretical models and numerical simulations to provide a molecular description of the interplay between a biomolecule and its environment. The manuscript is structured in two parts, addressing two complementary aspects of this complex interaction. In the first part we focus on the perturbation induced by a biomolecule on water molecules. We determine how much the hydration shell differs from bulk water and we identify the molecular factors at play. We then compare the hydration shells of an antifreeze protein and of a typical protein and investigate whether the shell structure and dynamics can explain the antifreeze properties. We finally study the hydration dynamics of a DNA dodecamer where slow water dynamics was suggested. We obtain a spatially resolved picture of DNA hydration and investigate the sources of heterogeneity. In the second part we examine the role of the environment in the chemical step of enzyme catalysis. We focus on two distinct systems with different questions, but relying on a common simulation methodology. We first examine the role of specific active site residues in catalysis by dihydrofolate reductase and we provide a molecular interpretation of recent experimental results. We finally study the role of water in enzyme catalysis in organic solvents, where addition of small amounts of water was shown to accelerate the chemical step. We seek a molecular scale description of this effect.
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Computer Modelling and Simulations of Enzymes and their MechanismsAlonso, Hernan, hernan.alonso@anu.edu.au January 2006 (has links)
Although the tremendous catalytic power of enzymes is widely recognized, their exact mechanisms of action are still a source of debate. In order to elucidate the origin of their power, it is necessary to look at individual residues and atoms, and establish their contribution to ligand binding, activation, and reaction. Given the present limitations of experimental techniques, only computational tools allow for such detailed analysis. During my PhD studies I have applied a variety of computational methods, reviewed in Chapter 2, to the study of two enzymes: DfrB dihydrofolate reductase (DHFR) and methyltetrahydrofolate: corrinoid/iron-sulfur protein methyltransferase (MeTr).
¶
The DfrB enzyme has intrigued microbiologists since it was discovered thirty years ago, because of its simple structure, enzymatic inefficiency, and its insensitivity to trimethoprim. This bacterial enzyme shows neither structural nor sequence similarity with its chromosomal counterpart, despite both catalysing the reduction of dihydrofolate (DHF) using NADPH as a cofactor. As numerous attempts to obtain experimental structures of an enzyme ternary complex have been unsuccessful, I combined docking studies and molecular dynamics simulations to produce a reliable model of the reactive DfrBDHFNADPH complex. These results, combined with published empirical data, showed that multiple binding modes of the ligands are possible within DfrB.
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Comprehensive sequence and structural analysis provided further insight into the DfrB family. The presence of the dfrB genes within integrons and their level of sequence conservation suggest that they are old structures that had been diverging well before the introduction of trimethoprim. Each monomer of the tetrameric active enzyme presents an SH3-fold domain; this is a eukaryotic auxiliary domain never found before as the sole domain of a protein, let alone as the catalytic one. Overall, DfrB DHFR seems to be a poorly adapted catalyst, a minimalistic enzyme that promotes the reaction by facilitating the approach of the ligands rather than by using specific catalytic residues.
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MeTr initiates the Wood-Ljungdahl pathway of anaerobic CO2 fixation. It catalyses the transfer of the N5-methyl group from N5-methyltetrahydrofolate (CH3THF) to the cobalt centre of a corrinoid/iron-sulfur protein. For the reaction to occur, the N5 position of CH3THF is expected to be activated by protonation. As experimental studies have led to conflicting suggestions, computational approaches were used to address the activation mechanism.
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Initially, I tested the accuracy of quantum mechanical (QM) methods to predict protonation positions and pKas of pterin, folate, and their analogues. Then, different protonation states of CH3THF and active-site aspartic residues were analysed. Fragment QM calculations suggested that the pKa of N5 in CH3THF is likely to increase upon protein binding. Further, ONIOM calculations which accounted for the complete protein structure indicated that active-site aspartic residues are likely to be protonated before the ligand. Finally, solvation and binding free energies of several protonated forms of CH3THF were compared using the thermodynamic integration approach. Taken together, these preliminary results suggest that further work with particular emphasis on the protonation state of active-site aspartic residues is needed in order to elucidate the protonation and activation mechanism of CH3THF within MeTr.
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Docking de compostos da família das ariloxazinas em enzimas relacionadas com a malária / Docking of arilloxazines in enzymes related to malariaCorrêa, Denis da Silva 06 August 2010 (has links)
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Previous issue date: 2010-08-06 / Universidade Federal de Minas Gerais / Malaria disease, caused mainly by Plasmodium falciparum parasite, afflicts about 500 million people and causes nearly one million deaths every year. For the development of new drugs against this disease, one possible approach is to identify an enzyme that plays a key role in P. falciparum development and presents significantly different properties from the corresponding human one. These differences can be exploited in the design of specific inhibitors of the parasite s protein, thus, three different enzymes were selected as possible targets. As there are evidences suggesting that increasing oxidative stress can effectively inhibit the growth of the malarial parasite the enzyme Glutathione Reductase of P. falciparum (PfGR), responsible for the parasite s antioxidant defense, has become a potential target for the design and development of inhibitors. The second target was the P. falciparum Dihydrofolate Reductase-Thymidylate Synthase (PfDHFR-TS), and in this case blocking its action stops the dTMP production and DNA synthesis in the parasite. The third chosen target was the P. falciparum Lactate Dehydrogenase (PfLDH), whose inhibition interrupts the ATP formation and thus causing the death of the parasite. So that a family of arilloxazines compounds, together with chloroquine and methylene blue, were studied by means of docking simulations in the binding sites of these enzymes and also in the corresponding human enzymes for comparison. The three-dimensional structures of the enzymes and of chloroquine and methylene blue were obtained from the Protein Data Bank (PDB). The structures of the arilloxazines compounds, in turn, were obtained by molecular modeling with HyperChem 6.01 and MOPAC2009 programs, using as starting models similar crystallographic structures deposited in the Cambridge Structural Database. Docking simulations were performed using GOLD 4.0.1. The docking results showed that the enzymes PfGR and PfDHFR-TS are not the preferential targets of chloroquine. For the methylene blue it was possible to elucidate its binding mode in hGR and PfGR. Regarding the arilloxazines it was possible to show that they present their higher affinity for hGR, followed by PfGR, hDHFR, PfDHFR-TS, PfLDH and hLDH. In the case of GRs, the interface site was the preferred binding site. The results suggest that if arilloxazines compounds with higher affinity for PfGR are desirable then a pentafluorophenyl should be attached at the N10 position, as in the 2e compound. When searching for arilloxazines with higher affinity for PfLDH, it seems to be desirable a carboxymethyl group at the N3 position (as in 5b) and a pentafluorophenyl group at N10 (as in 2e). Finally, the results suggest that in general the studied arilloxazines probably will present a higher affinity for hDHFR than PfDHFR-TS. All these results are an important starting point for the design of new arilloxazines ligands so that they can be used as lead compounds in the search for new drugs against malaria. / A malária, causada principalmente pelo Plasmodium falciparum, atinge cerca de 500 milhões de pessoas e causa aproximadamente um milhão de mortes todos os anos. Para o desenvolvimento de novos fármacos contra esta doença, uma das abordagens possível é identificar uma enzima que desempenhe papel vital no desenvolvimento do P. falciparum e apresente propriedades significantemente diferentes das enzimas humanas correspondentes, de modo que tais diferenças possam ser exploradas no design de inibidores específicos à proteína do parasita. Existem evidências sugerindo que aumentar o estresse oxidativo pode inibir eficientemente o crescimento do parasita causador da malária e, portanto, a enzima Glutationa Redutase do P. falciparum (GRPf), responsável por sua defesa antioxidante, tornou-se um alvo em potencial para o desenvolvimento de inibidores. Também, o bloqueio da ação da Diidrofolato Redutase-Timidilato Sintase do P. falciparum (DHFR-TSPf) interrompe a produção de dTMP e a síntese de DNA no parasita. Ainda, espera-se que a inibição da Lactato Desidrogenase do P. falciparum (LDHPf) interrompa a produção de ATP no parasita e, consequentemente, cause sua morte. Portanto, estudou-se o comportamento de compostos da família das ariloxazinas, da cloroquina e do azul de metileno nos sítios de ligação destas enzimas, além das enzimas humanas correspondentes para fins de comparação, por meio de cálculos de docking. As estruturas tridimensionais das enzimas foram obtidas no Protein Data Bank (PDB). As estruturas dos inibidores da família das ariloxazinas, por sua vez, foram obtidas por meio de modelagem molecular, utilizando os programas HyperChem 6.01 e MOPAC2009, a partir de estruturas cristalográficas semelhantes obtidas no Cambridge Structural Database; já as estruturas da cloroquina e do azul de metileno foram obtidas também no PDB. Os cálculos de docking destes compostos nos sítios de ligação das enzimas estudadas foram realizados utilizando o programa GOLD 4.0.1. Com base nos resultados de docking, sugere-se que as enzimas GRPf e DHFR-TSPf não são alvos preferenciais da cloroquina. Também, pôde-se elucidar o possível modo de ligação do azul de metileno nas enzimas GRh e GRPf. No geral, foi possível sugerir ainda que as ariloxazinas devam apresentar maior afinidade pela GRh, seguida por GRPf, DHFRh, DHFR-TSPf, LDHPf e LDHh, nesta ordem. Nas GRs, o sítio da interface foi o sítio preferencial de ligação. Para se buscar inibidores da família das ariloxazinas com maior afinidade pela GRPf, sugere-se considerar um pentafluorfenil como substituinte na posição N10, como no composto 2e. Ainda, na busca por ariloxazinas com maior afinidade pela LDHPf, sugere-se considerar um carboximetil na posição N3 (como o de 5b) e um pentafluorfenil na posição N10 (como em 2e). Por fim, foi obtido que as ariloxazinas estudadas possivelmente apresentarão, em geral, uma maior afinidade pela DHFRh do que pela DHFR-TSPf. Estes dados podem ser tomados como ponto de partida para o design de novos compostos da família das ariloxazinas, a fim de que possam atuar como compostos líderes na busca por novos fármacos contra a malária.
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Cell lines and animal model in the analysis of pharmacogenomics markers in childhood acute lymphoblastic leukemiaSharif Askari, Bahram 09 1900 (has links)
La leucémie aiguë lymphoblastique (LAL) est le cancer pédiatrique le plus fréquent. Elle est la cause principale de mortalité liée au cancer chez les enfants due à un groupe de patient ne répondant pas au traitement. Les patients peuvent aussi souffrir de plusieurs toxicités associées à un traitement intensif de chimiothérapie. Les études en pharmacogénétique de notre groupe ont montré une corrélation tant individuelle que combinée entre les variants génétiques particuliers d’enzymes dépendantes du folate, particulièrement la dihydrofolate réductase (DHFR) ainsi que la thymidylate synthase (TS), principales cibles du méthotrexate (MTX) et le risque élevé de rechute chez les patients atteints de la LAL. En outre, des variations dans le gène ATF5 impliqué dans la régulation de l’asparagine synthetase (ASNS) sont associées à un risque plus élevé de rechute ou à une toxicité ASNase dépendante chez les patients ayant reçu de l’asparaginase d’E.coli (ASNase). Le but principal de mon projet de thèse est de comprendre davantage d’un point de vue fonctionnel, le rôle de variations génétiques dans la réponse thérapeutique chez les patients atteints de la LAL, en se concentrant sur deux composants majeurs du traitement de la LAL soit le MTX ainsi que l’ASNase.
Mon objectif spécifique était d’analyser une association trouvée dans des paramètres cliniques par le biais d’essais de prolifération cellulaire de lignées cellulaires lymphoblastoïdes (LCLs, n=93) et d’un modèle murin de xénogreffe de la LAL. Une variation génétique dans le polymorphisme TS (homozygosité de l’allèle de la répétition triple 3R) ainsi que l’haplotype *1b de DHFR (défini par une combinaison particulière d’allèle dérivé de six sites polymorphiques dans le promoteur majeur et mineur de DHFR) et de leurs effets sur la sensibilité au MTX ont été évalués par le biais d’essais de prolifération cellulaire. Des essais in vitro similaires sur la réponse à l’ASNase de E. Coli ont permis d’évaluer l’effet de la variation T1562C de la région 5’UTR de ATF5 ainsi que des haplotypes particuliers du gène ASNS (définis par deux variations génétiques et arbitrairement appelés haplotype *1). Le modèle murin de xénogreffe ont été utilisé pour évaluer l’effet du génotype 3R3R du gène TS.
L’analyse de polymorphismes additionnels dans le gène ASNS a révélé une diversification de l’haplotype *1 en 5 sous-types définis par deux polymorphismes (rs10486009 et rs6971012,) et corrélé avec la sensibilité in vitro à l’ASNase et l’un d’eux (rs10486009) semble particulièrement important dans la réduction de la sensibilité in vitro à l’ASNase, pouvant expliquer une sensibilité réduite de l’haplotype *1 dans des paramètres cliniques. Aucune association entre ATF5 T1562C et des essais de prolifération cellulaire en réponse à ASNase de E.Coli n’a été détectée.
Nous n’avons pas détecté une association liée au génotype lors d’analyse in vitro de sensibilité au MTX. Par contre, des résultats in vivo issus de modèle murin de xénogreffe ont montré une relation entre le génotype TS 3R/3R et la résistance de manière dose-dépendante au traitement par MTX. Les résultats obtenus ont permis de fournir une explication concernant un haut risque significatif de rechute rencontré chez les patients au génotype TS 3R/3R et suggèrent que ces patients pourraient recevoir une augmentation de leur dose de MTX. À travers ces expériences, nous avons aussi démontré que les modèles murins de xénogreffe peuvent servir comme outil préclinique afin d’explorer l’option d’un traitement individualisé.
En conclusion, la connaissance acquise à travers mon projet de thèse a permis de confirmer et/ou d’identifier quelques variants dans la voix d’action du MTX et de l’ASNase qui pourraient faciliter la mise en place de stratégies d’individualisation de la dose, permettant la sélection d’un traitement optimum ou moduler la thérapie basé sur la génétique individuelle. / Acute lymphoblastic leukemia (ALL) is the most frequent malignancy of childhood. It is the principal cause of cancer–related mortality in children due to a persistent group of patients who does not respond to standard anti-cancer treatment. Susceptible patients may also suffer from number of toxicities associated with intensive chemotherapy treatment. Pharmacogenetic studies of our group, showed that particular genetic variants of the folate dependent enzymes, particularly, dihydrofolate reductase (DHFR) and thymidylate synthase (TS), major targets of methotrexate (MTX), correlate both individually and combined with increased risk of relapse in patients with childhood ALL. Furthermore, variations of ATF5 gene involved in asparagine synthetase (ASNS) regulation and of ASNS gene were associated with higher risk of ALL relapse or with ASNase related toxicity in patients who received E.coli asparaginase (ASNase). The major goal of my doctoral research project was to further understand from the functional point of view the role of genetic variations underlying therapeutic responses of childhood ALL, by focusing on two major components of ALL treatment, MTX and ASNase.
My specific goal was to analyze associations found in clinical setting using cellular proliferation assay in lymphoblastoid cell lines (LCLs, n=93) and xenograft mice model of ALL. Genetic variation in TS polymorphism (homozygosity for triple repeat allele, 3R) and of DFHR haplotype *1b (defined by particular allelic combination derived from six polymorphic sites in the major and minor promoter of DHFR), on MTX sensitivity was assessed using cellular proliferation assay. Similar in vitro assay in response to E.coli ASNase was used to access the T1562C variation in the ATF5 5’UTR and particular haplotypes of ASNS gene (defined by two genetic variation and arbitrarily named haplotype *1). Xenograft mouse model was used to access the effect of TS 3R3R genotype.
Analysis of additional polymorphisms in ASNS gene revealed diversification of haplotype *1 of ASNS gene in 5 subtypes, two polymorphisms (rs10486009 and rs6971012,) defining particular subtypes correlated with in vitro sensitivity to ASNase and one of them (rs10486009) seems particularly important for reducing sensitivity to ASNase in vitro, possibly providing mechanistic explanation for lower sensitivity of haplotype *1 observed in clinical setting. No association between ATF5 T1562C variation and cellular proliferation assay in response to E.coli ASNase was found.
We did not observe genotype-related association when in vitro sensitivity to MTX in LCLs was analyzed. In contrast, in vivo results using xenograft mouse model demonstrated the relationship between the TS 3R/3R genotype and the resistance to MTX treatment in dose-dependent manner. Obtained results provided function explanation for the significantly higher risk of relapse seen in 3R/3R ALL patients and suggest that these patients might benefit from increase dose of MTX. Through these experiments we also showed that xenogeneic mice model can serve as a preclinical tool to explore individualized treatment options.
In conclusion, the knowledge acquired through my doctoral work confirmed and/or identified some functional variants in MTX and ASNase action pathway which may facilitate dose individualization strategies, allowing for optimal treatment selection or tailoring childhood ALL therapy based on individual genetics.
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Pharmacogénétique du DHFR chez les enfants leucémiquesAl-Shakfa, Fidaa 04 1900 (has links)
Le dihydrofolate réductase (DHFR) est la principale cible du méthotrexate, un important composant du traitement de la leucémie lymphoblastique aiguë (LLA). Une association des polymorphismes du promoteur de DHFR avec l’issue de la LLA a été mise en évidence au laboratoire. Une survie sans événement (EFS) réduite corrélait avec les allèles A -317 et C -1610, et l’haplotype *1, défini par ces allèles. L’haplotype *1 était aussi associé à une expression élevée du DHFR. Dans cette étude, nous étendons l’analyse à la région régulatrice adjacente, d’environ 400 pb, correspondant au transcrit mineur non-codant du DHFR, qui joue un rôle essentiel dans la régulation de la transcription au niveau du promoteur majeur. Six polymorphismes ont été identifiés, parmi lesquels 5 étaient des SNPs et un polymorphisme de longueur composé d’un nombre variable d’éléments de 9 pb et d’une insertion/délétion de 9 pb. L’analyse d’haplotype, incluant tous les polymorphismes promoteurs, a révélé une diversification de l’haploytpe *1 en 5 sous-types (*1a à *1e). Les variations du promoteur majeur et les sous-types de l’haplotype *1 ont été par la suite analysés pour l’association avec l’issue de LLA. Un EFS réduit corrélait avec l’allèle A du polymorphisme G308A (p=0,02) et avec l’haplotype *1 (p=0,01). Des niveaux élevées d’ARNm étaient trouvés chez les porteurs de l’haplotype *1b (p=0,005) et pas pour les autres sous-types de l’haplotype *1. Alors, la mauvaise issue de LLA associée avec l'haplotype *1 est en effet déterminée par le sous-type *1b. Cette étude donne un nouvel aperçu des polymorphismes régulateurs du DHFR définissant plus précisément les variations du DHFR prédisposant un événement. / Dihydrofolate reductase (DHFR) is the major target of methotrexate, a key component in childhood acute lymphoblastic leukemia (ALL) treatment. We recently reported an association of DHFR promoter polymorphisms with ALL outcome. Lower event free survival (EFS) correlated with the alleles A -317 and C -1610, and with haplotype *1, defined by these alleles. Haplotype*1 was also associated higher DHFR expression. Here we extended the analysis to adjacent 400bp regulatory region corresponding to non-coding minor DHFR transcript which plays an essential role in the regulation of transcription from the major promoter. Six polymorphisms were identified, of which 5 were SNPs and one length polymorphism composed of variable number of 9bp elements and 9bp insertion/deletion. Haplotype analysis including all promoter polymorphisms revealed diversification of haplotype *1 into 5 subtypes (*1a to *1e). Major promoter variations and haplotype *1 subtypes were subsequently analyzed for the association with ALL outcome. Lower EFS correlated with an A allele of G308A polymorphism (p=0.02) and with *1b haplotype (p=0.01). Higher mRNA levels were found in the carriers of *1b haplotype (p=0.005) and not for remaining haplotype *1 subtypes. So, the worse ALL outcome associated with haplotype *1 is actually determined by the subtype *1b. The study provides a new insight into DHFR regulatory polymorphisms defining more precisely event–predisposing DHFR variations.
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Triagem virtual de inibidores da enzima di-hidrofolato redutase de Schistosoma mansoni (SmDHFR) / Virtual screening of dihydrofolate reductase Schistosoma mansoni (SmDHFR) enzyme inhibitors.Martins, João Paulo Machado 17 August 2017 (has links)
A esquistossomose é uma das principais causas de morbidade em países Tropicais e Subtropicais, gerando graves consequências socioeconômicas. Atualmente, os fármacos disponíveis para o tratamento da desta doença são praziquantel e oxamniquina, porém relatos de baixa susceptibilidade do parasita a esses medicamentos sugerem a necessidade de novas estratégias terapêuticas para o tratamento da doença. Todavia, existe pouco interesse da indústria farmacêutica no desenvolvimento de fármacos contra doenças tropicais e negligenciadas, entre as quais se encontra a esquistossomose. Devido a estes fatores, o presente trabalho teve por objetivo geral utilizar ferramentas computacionais para identificar inibidores da SmDHFR candidatos a novos fármacos. Avaliou-se as características exclusivas para a proteína de S. mansoni por meio de uma análise das sequências FASTA em comparação com a DHFR de outros organismos. A fim de garantir a ação seletiva dessas moléculas frente a enzima do parasita, os campos moleculares de interação seletivos para SmDHFR foram calculados e empregados na construção do modelo farmacofórico, o qual foi utilizado na triagem virtual de inibidores de SmDHFR. Os estudos computacionais realizados nos permitiram a seleção de 20 moléculas com uma boa complementariedade com o modelo farmacofórico gerado e com potencial para serem inibidores de SmDHFR. / Schistosomiasis is one of morbidity\'s main causes in tropical and subtropical countries, which leads to serious socioeconomic consequences. Praziquantel and oxamniquina are the drugs currently available for treating this disease, but reports points that the parasite has been resistant to both drugs, which suggests the need for new therapeutic strategies for the treatment of this disease. However, there is little interest in the pharmaceutical industry in developing drugs against neglected tropical diseases, including schistosomiasis. Due to these factors, the present work has the general objective to use computational tools to identify SmDHFR inhibitors which could be good candidates for developing new drugs. Evaluation of the exclusive characteristics of the S. mansoni protein were performed by FASTA sequence analyses in comparison to DHFR from other organisms. In order to guarantee the selective action of these molecules against the parasite enzyme, the molecular interaction fields selective for SmDHFR were calculated and used in the construction of the pharmacophoric model, which was further used in the virtual screening of SmDHFR inhibitors. Computational studies were performed and those led us to 20 molecules with a good complementarity with the pharmacophoric model that was previously generated and with potential to be SmDHFR inhibitors.
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Découverte d'inhibiteurs de la dihydrofolate réductase R67 impliquée dans la résistance au triméthoprimeBastien, Dominic 08 1900 (has links)
No description available.
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Découverte d'inhibiteurs de la dihydrofolate réductase R67 impliquée dans la résistance au triméthoprime.Bastien, Dominic 08 1900 (has links)
Le triméthoprime (TMP) est un antibiotique communément utilisé depuis les années 60. Le TMP est un inhibiteur de la dihydrofolate réductase (DHFR) bactérienne chromosomale. Cette enzyme est responsable de la réduction du dihydrofolate (DHF) en tétrahydrofolate (THF) chez les bactéries, qui lui, est essentiel à la synthèse des purines et ainsi, à la prolifération cellulaire. La résistance bactérienne au TMP est documentée depuis plus de 30 ans. Une des causes de cette résistance provient du fait que certaines souches bactériennes expriment une DHFR plasmidique, la DHFR R67. La DHFR R67 n'est pas affectée par le TMP, et peut ainsi remplacer la DHFR chromosomale lorsque celle-ci est inhibée par le TMP. À ce jour, aucun inhibiteur spécifique de la DHFR R67 est connu. En découvrant des inhibiteurs contre la DHFR R67, il serait possible de lever la résistance au TMP que la DHFR R67 confère aux bactéries.
Afin de découvrir des inhibiteurs de DHFR R67, les approches de design à base de fragments et de criblage virtuel ont été choisies. L'approche de design à base de fragments a permis d'identifier sept composés simples et de faible poids moléculaire (fragments) inhibant faiblement la DHFR R67. À partir de ces fragments, des composés plus complexes et symétriques, inhibant la DHFR R67 dans l'ordre du micromolaire, ont été élaborés. Des études cinétiques ont montré que ces inhibiteurs sont compétitifs et qu'au moins deux molécules se lient simultanément dans le site actif de la DHFR R67. L'étude d'analogues des inhibiteurs micromolaires de la DHFR R67 a permis de déterminer que la présence de groupements carboxylate, benzimidazole et que la longueur des molécules influencent la puissance des inhibiteurs. Une étude par arrimage moléculaire, appuyée par les résultats in vitro, a permis d'élaborer un modèle qui suggère que les résidus Lys32, Gln67 et Ile68 seraient impliqués dans la liaison avec les inhibiteurs. Le criblage virtuel de la librairie de 80 000 composés de Maybridge avec le logiciel Moldock, et les essais d'inhibition in vitro des meilleurs candidats, a permis d'identifier quatre inhibiteurs micromolaires appartenant à des familles distinctes des composés précédemment identifiés. Un second criblage virtuel, d'une banque de 6 millions de composés, a permis d'identifier trois inhibiteurs micromolaires toujours distincts. Ces résultats offrent la base à partir de laquelle il sera possible de développer
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des composés plus efficaces et possédant des propriétés phamacologiquement acceptables dans le but de développer un antibiotique pouvant lever la résistance au TMP conféré par la DHFR R67. / Trimethoprim (TMP) is a common antibiotic which is used since the 60's. TMP is an inhibitor of the bacterial chromosomal dihydrofolate reductase (DHFR). This enzyme catalyses the reduction of the dihydrofolate (DHF) to tetrahydrofolate (THF) which is essential to the biosynthesis of purines thus to cellular proliferation. Bacterial TMP resistance is documented since about 30 years. One of the cause of this resistance comes from the fact that certain bacteria express a plasmidic DHFR, the R67 DHFR, which confers TMP resistance. The R67 DHFR is not inhibited by TMP and can replace the chromosomal DHFR when the latter is inhibited by TMP. The discovery of R67 DHFR inhibitors would allow to break the trimethoprim resistance granted by R67 DHFR.
In order to discover R67 DHFR inhibitors, fragment based design and virtual screening approaches were selected. By fragment based design, seven simple compounds with a low molecular mass which inhibited weakly R67 DHFR (fragments) were identified. From these fragments, more complex and symmetrical compounds inhibiting R67 DHFR in the micromolar range were identified. Kinetic studies showed these inhibitors were competitive and at least two molecules bind simultaneously to the active site of the R67 DHFR. Test of the micromolar inhibitors analog showed that the presence of carboxylate, benzimidazole and the length of the molecule all have an effect on the potency of the inhibitors. Molecular docking of the inhibitors, supported by in vitro data, were used to develop a model which suggest that residue like Lys32, Gln67 and Ile68 would be involved in the binding of the inhibitors to the R67 DHFR. Virtual screening of the 80 000 compound Maybridge library with Moldock software, followed by in vitro test of the best candidate, identified four micromolar inhibitors which are chemically distinct from the inhibitor beforehand identified. A second virtual screening of a 6 million compounds bank identified three micromolar inhibitors which are also distinct from the inhibitor beforehand identified.
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These results offer a basis which will allow further development of more potent inhibitors with more acceptable pharmacologic properties in order to develop an antibiotic which would break the TMP resistance granted by the R67 DHFR.
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Pharmacogénétique du DHFR chez les enfants leucémiquesAl-Shakfa, Fidaa 04 1900 (has links)
Le dihydrofolate réductase (DHFR) est la principale cible du méthotrexate, un important composant du traitement de la leucémie lymphoblastique aiguë (LLA). Une association des polymorphismes du promoteur de DHFR avec l’issue de la LLA a été mise en évidence au laboratoire. Une survie sans événement (EFS) réduite corrélait avec les allèles A -317 et C -1610, et l’haplotype *1, défini par ces allèles. L’haplotype *1 était aussi associé à une expression élevée du DHFR. Dans cette étude, nous étendons l’analyse à la région régulatrice adjacente, d’environ 400 pb, correspondant au transcrit mineur non-codant du DHFR, qui joue un rôle essentiel dans la régulation de la transcription au niveau du promoteur majeur. Six polymorphismes ont été identifiés, parmi lesquels 5 étaient des SNPs et un polymorphisme de longueur composé d’un nombre variable d’éléments de 9 pb et d’une insertion/délétion de 9 pb. L’analyse d’haplotype, incluant tous les polymorphismes promoteurs, a révélé une diversification de l’haploytpe *1 en 5 sous-types (*1a à *1e). Les variations du promoteur majeur et les sous-types de l’haplotype *1 ont été par la suite analysés pour l’association avec l’issue de LLA. Un EFS réduit corrélait avec l’allèle A du polymorphisme G308A (p=0,02) et avec l’haplotype *1 (p=0,01). Des niveaux élevées d’ARNm étaient trouvés chez les porteurs de l’haplotype *1b (p=0,005) et pas pour les autres sous-types de l’haplotype *1. Alors, la mauvaise issue de LLA associée avec l'haplotype *1 est en effet déterminée par le sous-type *1b. Cette étude donne un nouvel aperçu des polymorphismes régulateurs du DHFR définissant plus précisément les variations du DHFR prédisposant un événement. / Dihydrofolate reductase (DHFR) is the major target of methotrexate, a key component in childhood acute lymphoblastic leukemia (ALL) treatment. We recently reported an association of DHFR promoter polymorphisms with ALL outcome. Lower event free survival (EFS) correlated with the alleles A -317 and C -1610, and with haplotype *1, defined by these alleles. Haplotype*1 was also associated higher DHFR expression. Here we extended the analysis to adjacent 400bp regulatory region corresponding to non-coding minor DHFR transcript which plays an essential role in the regulation of transcription from the major promoter. Six polymorphisms were identified, of which 5 were SNPs and one length polymorphism composed of variable number of 9bp elements and 9bp insertion/deletion. Haplotype analysis including all promoter polymorphisms revealed diversification of haplotype *1 into 5 subtypes (*1a to *1e). Major promoter variations and haplotype *1 subtypes were subsequently analyzed for the association with ALL outcome. Lower EFS correlated with an A allele of G308A polymorphism (p=0.02) and with *1b haplotype (p=0.01). Higher mRNA levels were found in the carriers of *1b haplotype (p=0.005) and not for remaining haplotype *1 subtypes. So, the worse ALL outcome associated with haplotype *1 is actually determined by the subtype *1b. The study provides a new insight into DHFR regulatory polymorphisms defining more precisely event–predisposing DHFR variations.
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Triagem virtual de inibidores da enzima di-hidrofolato redutase de Schistosoma mansoni (SmDHFR) / Virtual screening of dihydrofolate reductase Schistosoma mansoni (SmDHFR) enzyme inhibitors.João Paulo Machado Martins 17 August 2017 (has links)
A esquistossomose é uma das principais causas de morbidade em países Tropicais e Subtropicais, gerando graves consequências socioeconômicas. Atualmente, os fármacos disponíveis para o tratamento da desta doença são praziquantel e oxamniquina, porém relatos de baixa susceptibilidade do parasita a esses medicamentos sugerem a necessidade de novas estratégias terapêuticas para o tratamento da doença. Todavia, existe pouco interesse da indústria farmacêutica no desenvolvimento de fármacos contra doenças tropicais e negligenciadas, entre as quais se encontra a esquistossomose. Devido a estes fatores, o presente trabalho teve por objetivo geral utilizar ferramentas computacionais para identificar inibidores da SmDHFR candidatos a novos fármacos. Avaliou-se as características exclusivas para a proteína de S. mansoni por meio de uma análise das sequências FASTA em comparação com a DHFR de outros organismos. A fim de garantir a ação seletiva dessas moléculas frente a enzima do parasita, os campos moleculares de interação seletivos para SmDHFR foram calculados e empregados na construção do modelo farmacofórico, o qual foi utilizado na triagem virtual de inibidores de SmDHFR. Os estudos computacionais realizados nos permitiram a seleção de 20 moléculas com uma boa complementariedade com o modelo farmacofórico gerado e com potencial para serem inibidores de SmDHFR. / Schistosomiasis is one of morbidity\'s main causes in tropical and subtropical countries, which leads to serious socioeconomic consequences. Praziquantel and oxamniquina are the drugs currently available for treating this disease, but reports points that the parasite has been resistant to both drugs, which suggests the need for new therapeutic strategies for the treatment of this disease. However, there is little interest in the pharmaceutical industry in developing drugs against neglected tropical diseases, including schistosomiasis. Due to these factors, the present work has the general objective to use computational tools to identify SmDHFR inhibitors which could be good candidates for developing new drugs. Evaluation of the exclusive characteristics of the S. mansoni protein were performed by FASTA sequence analyses in comparison to DHFR from other organisms. In order to guarantee the selective action of these molecules against the parasite enzyme, the molecular interaction fields selective for SmDHFR were calculated and used in the construction of the pharmacophoric model, which was further used in the virtual screening of SmDHFR inhibitors. Computational studies were performed and those led us to 20 molecules with a good complementarity with the pharmacophoric model that was previously generated and with potential to be SmDHFR inhibitors.
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