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Mutational analysis of the rifampicin glycosyl-transferase (rgt) inactivation protein from Nocardia brasiliensis and its relationship to the vancomycin resistance of this organismBaker, Alison Saxe 16 November 2006 (has links)
Student Number : 0418251N -
MSc research report -
School of Molecular and Cell Biology -
Faculty of Science / Rifampicin is a chemotherapeutic agent used to combat mycobacterial and nocardial
infections. Four enzymatic inactivation mechanisms have been identified which are
partially responsible for the increasing number of rifampicin resistant strains. These are
ADP-ribosylation, phosphorylation, decomposition and glucosylation. The gene encoding
the latter, rgt, has been cloned and characterized from the opportunistic pathogen
Nocardia brasiliensis. However, as of yet nothing is known of these inactivation
enzymes. Thus in order to study the properties of the mechanism it is necessary to
observe structure-function relationships through the characterization of mutants.
Furthermore, the rgt gene confers a small yet reproducible increase to the vancomycin
MIC. This has indicated that there may be other enzymatic mechanisms which are
involved in the inactivation of vancomycin. Vancomycin is an important antibiotic as it is
used to treat gram-positive infections by multi-drug resistant strains. Hitherto, no
mechanisms of enzymatic inactivation have been identified for vancomycin. Thus in
order to identify regions of DNA which may play a role in the high level resistance to
vancomycin as observed in N. brasiliensis it was necessary to screen a genomic library of
this organism. This was performed in a gram-positive background. No clones were
identified in this study that had an increased resistance to vancomycin, indicating that the
DNA involved in the phenotype is greater than that of the average insert size of the
library, 1.9 kb.
Future work will thus involve the generation of a genomic library with larger fragments
and the subsequent screening of this. Additionally, performing a mutational analysis on
the rgt gene may provide further insight into the specifics of the inactivation enzymes and
thus will contribute to combating infection by opportunistic and other pathogens.
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Désordres de l'homéostasie lipidique durant le développement du diabète non-insulino dépendant chez le psammomys obesusZoltowska, Monika January 2002 (has links)
Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.
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Contribution à la compréhension du mécanisme de formation de dextranes ou gluco-oligosaccharides ramifiés en alpha-1,2 par l'enzyme GBD-CD2 : études cinétique et structurale / Contribution to the understanding of the alpha-(1→2) branching mechanism of dextrans and gluco-oligosaccharides by GBD-CD2 enzyme : kinetic and structural studiesBrison, Yoann 20 September 2010 (has links)
Issue de la troncature de la dextrane-saccharase DSR-E, l’alpha-(1→2) transglucosidase recombinante GBD-CD2 catalyse à partir de saccharose le branchement de molécules acceptrices tels que les dextranes, les isomalto-oligosaccharides ou les gluco-oligosaccharides (GOS ; [6)-alpha-D-Glcp-(1→]n-alpha-D-Glcp-(1→4)-D-Glcp, avec 1<n<9). L’objet de cette étude a porté sur la compréhension des relations structure-activité de GBD-CD2 afin d’investiguer les facteurs structuraux responsables de la synthèse des liaisons osidiques de type alpha-(1→2). La troncature rationnelle du domaine de liaison au glucane (GBD) de l’enzyme GBD-CD2 (192 kDa) a abouti à l’isolement de trois formes tronquées actives, de masses moléculaires égales à 180, 147 et 123 kDa. Après purification de GBD-CD2 et de delta N123-GBD-CD2 (123 kDa), des études cinétiques ont permis de mettre en évidence que les enzymes présentent la même régiospécificité. L’activité d’hydrolyse du saccharose peut être modélisée par le modèle de Michaelis – Menten (kcat respectifs de 109 et 76 s-1). En présence de dextrane accepteur, ces enzymes sont activées. L’activité d’alpha-(1→2) glucosylation suit un modèle Ping Pong Bi Bi (kcat respectifs de 970 et 947 s-1). En modulant le ratio molaire entre le donneur d’unités glucosyle et l’accepteur de ces unités ([saccharose]/[dextrane]), il est possible de synthétiser des dextranes dont le pourcentage de liaisons alpha-(1→2) est contrôlé et varie de 10% à 40%. La caractérisation des produits de la réaction menée en présence de saccharose et de GOS a permis d’isoler et de caractériser pour la première fois des GOS arborant des unités glucosyle branchées en alpha-(1→2) sur les unités glucosyle adjacentes de la chaîne principale. Enfin, la résolution de la structure de delta N123-GBD-CD2 à 3,2 Å révèle que cette enzyme adopte le repliement original « en U » similaire à celui décrit pour GTF180-delta N. La comparaison des gorges catalytiques des deux dextrane-saccharases cristallisées apporte des éléments pouvant expliquer la régiospécificité singulière de delta N123-GBD-CD2, et ouvre la voie à des travaux de mutagenèse visant à investiguer le rôle de résidus potentiellement clés / GBD-CD2 is a recombinant alpha-(1→2) transglucosidase constructed by truncation of the DSR-E dextransucrase from Leuconostoc mesenteroides NRRL B-1299. From sucrose, GBD-CD2 catalyses the alpha-(1→2) branching reaction onto acceptor molecules such as dextrans, isomalto-oligosaccharides or gluco-oligosaccharides (GOS; [6)-alpha-D-Glcp-(1→]n-alpha-D-Glcp-(1→4)-D-Glcp, 1<n<9). This work has been focused on structure activity relationship studies. Rational truncations of the glucan binding domain (GBD) led to the expression in E. coli of three active enzymes, showing molecular masses of 180, 147 and 123 kDa. After purification of the recombinant GBD-CD2 and delta N123-GBD-CD2, we showed that both enzymes display the same regiospecificity. Steady-state kinetics revealed that the activity of sucrose hydrolysis displays a Michaelis Menten type of kinetics (kcat 109 s-1 and 76 s-1, respectively). In the presence of dextran acceptor, these enzymes are activated. The alpha-(1→2) transglucosidase activity from sucrose onto dextrans was modelled by a Ping Pong Bi Bi mechanism (kcat 970 s-1 and 947 s-1, respectively). When varying the molar ratio between the glucosyl donor and the acceptor ([sucrose]/[dextran]), the percentage of alpha-(1→2) linkages in dextrans can be controlled from 10% to 40%. Additionally, from reactions in the presence of GOS and sucrose, we isolated and characterized new alpha-(1→2) branched GOS with contiguous alpha-(1→2) branchings along linear GOS chains. Finally, the X-ray structure of delta N123-GBD-CD2 at 3.2 Å resolution revealed that this enzyme has a very original “U folding” similar to that described for GTF180-delta N. Study of the residues lining the catalytic gorges of the two crystallized enzymes revealed the structural determinants possibly involved in the singular regiospecificity of delta N123-GBD-CD2. Our work opens the way to mutagenesis work for discovering key structural determinants of delta N123-GBD-CD2
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Molecular evolutionary perspectives of amylosucrases : from natural substrate promiscuity to tailored catalysis / Perspectives sur l’évolution moléculaire des amylosaccharases : De la promiscuité de substrat naturelle vers une catalyse contrôléeDaude, David 02 July 2013 (has links)
La promiscuité des enzymes joue un rôle primordial pour l’évolution des protéines et la divergence des fonctions catalytiques. Comprendre les déterminants moléculaires qui régissent cette promiscuité enzymatique représente un enjeu scientifique majeur pour identifier les trajectoires évolutives pouvant entrainer l’émergence de nouvelles fonctions. L’objectif de cette thèse a consisté d’une part à sonder la promiscuité catalytique de l’amylosaccharase de Neisseria polysaccharea, une transglucosidase d’intérêt biotechnologique majeur, dans le but d’identifier des substrats alternatifs et d’autre part à étendre ses capacités naturelles par des techniques d’évolution moléculaire. Une trentaine de molécules ont été testées et ont permis de mettre en évidence la forte spécificité de l’enzyme pour son substrat donneur ainsi que sa large promiscuité vers les substrats accepteurs. Le rôle des résidus impliqués dans la reconnaissance des substrats a par la suite été considéré au travers d’une stratégie rationnelle basée sur des prévisions de stabilité thermodynamique. Deux histidines (H187 et H392), ont ainsi été ciblées par mutagénèse à saturation. La stabilité de ces mutants a été étudiée ainsi que ainsi que leur activité envers différents substrats. Des enzymes à la stabilité améliorée ou montrant des changements de spécificité de produits ont ainsi été identifiées. Afin d’étudier plus amplement la promiscuité de cette amylosaccharase, une deuxième stratégie d’ingénierie a été menée pour mimer in vitro les mécanismes moléculaires de la dérive génétique neutre. Ce phénomène dit de “Neutral-Drift” a préalablement été décrit comme un facteur impliqué dans les changements de promiscuité catalytique. Quatre cycles de mutagénèse ont ainsi été réalisés et 440 clones ont été sélectionnés pour avoir conservé leur fonction originelle (i.e. leur activité sur saccharose). Des variants aux propriétés catalytiques améliorées envers des substrats alternatifs ont été caractérisés et des groupes de positions corrélées ont été identifiés. L’effet des mutations neutres sur la thermostabilité a également été étudié. Enfin, de façon remarquable, une nouvelle activité envers un substrat non reconnu par l’enzyme native, le méthyl-α-L-rhamnopyranoside, a été détectée. Ce variant possédant quatre substitutions a été caractérisé et la résolution de sa structure tridimensionnelle par cristallographie aux rayons-X permettra d’approfondir les relations unissant séquence, structure et activité de l’enzyme / Investigation of substrate promiscuity is of prime interest to understand the way enzymes evolve. Understanding the molecular determinants involved in substrate promiscuity is challenging to determine the evolutionary trajectories that lead to the emergence of catalytic functions and to take further advantage of their evolvability to develop original biocatalysts. The objective of this thesis aimed to investigate the substrate promiscuity of the amylosucrase from Neisseria polysaccharea, a transglucosidase of prime biotechnological interest, to identify alternative donor and acceptor molecules and further extend its catalytic properties through enzyme engineering. About thirty molecules were assayed and the strong specificity for the natural donor sucrose was emphasized, as well as the broad acceptor promiscuity. The rational engineering of active site residues responsible for substrate recognition was undertaken through thermodynamic stability predictions. Two residues, namely H187 and H392, were rationally targeted for site-directed mutagenesis. The stability of these variants was investigated as well as their activity toward both natural and promiscuous substrates. Variants with enhanced stability or altered product distribution were identified. These results highlighted that mutations responsible for stability changes may also lead to substrate promiscuity or product specificity changes. To further investigate the promiscuity of amylosucrase, we considered another engineering strategy to mimic in vitro the neutral enzyme evolution. Neutral genetic drift was previously shown to be related to promiscuity changes. On this basis, four repeated round of mutagenesis were performed and 440 clones were selected because they maintained the protein original function (i.e. the activity on sucrose). Variants with enhanced properties towards promiscuous donors and acceptors were characterized and clusters of correlated amino acid substitutions were identified. The impact of neutral mutations on thermodynamic stability was also discussed. Remarkably, a totally new activity towards methyl-α-L-rhamnopyranoside, an acceptor not recognized by the parental wild-type enzyme, was detected. The variant harboring four amino acid substitutions was characterized and the determination of its three-dimensional structure by X-ray crystallography will be useful to further investigate the structure-sequence-activity relationships of this enzyme
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Computer-aided design and engineering of sucrose-utilizing transglucosylases for oligosaccharide synthesis / Design computationnel et ingénierie de transglycosylases pour la synthèse d'oligosaccharidesVerges, Alizee 08 April 2015 (has links)
La synthèse d’oligosides complexes reste difficilement réalisable par voie chimique. Le recours aux catalyseurs enzymatiques permettrait de pallier aux contraintes de la chimie mais les enzymes naturelles ne présentent pas toujours les propriétés adéquates et nécessitent d’être optimisées par ingénierie moléculaire. Le couplage de la chimie et de biocatalyseurs conçus « sur mesure », peut offrir une alternative prometteuse pour explorer de nouvelles voies de synthèse des sucres, notamment pour la mise au point de glycovaccins. L’objectif de cette thèse a ainsi visé à mettre en œuvre des stratégies d’ingénierie semi-rationnelles de l’amylosaccharase de Neisseria polysaccharea (ASNp), une α-transglucosylase utilisant le saccharose comme substrat, afin de concevoir de nouvelles spécificités de substrats et d’étendre le potentiel de cette enzyme à catalyser de nouvelles réactions, permettant ainsi d’aller bien au-delà de ce que la Nature peut offrir. Dans une première étude, une approche assistée par ordinateur a été suivie afin de remodeler le site actif de l’enzyme (sous-sites +1, +2 et +3) pour la reconnaissance et la glucosylation en α-1,4 d’un accepteur disaccharidique non-naturel (l’allyl 2-deoxy-2-N-trichloroacetyl-β-D-glucopyranosyl-(1→2)-α-L-rhamnopyranose). Le produit attendu, un trisaccharide, est un précurseur dans la synthèse chimio-enzymatique des oligosaccharides mimant les unités répétitives des lipopolysaccharides de Shigella flexneri, dont l’utilisation ultime est le développement de vaccins contre la Shigellose. Une approche computationnelle faisant appel à des outils dédiés au design automatisé de protéines et à une analyse des séquences a conduit au design d’une librairie d’environ 2.7x104 séquences, qui a ensuite été construite expérimentalement puis criblée. Au final, 55 variants actifs sur saccharose (le substrat donneur) ont été identifiés, et un mutant, appelé F3, a révélé sa capacité à glucosyler en α-1,4 le disaccharide cible. De manière étonnante, ce mutant possède 7 mutations au sein de son site actif, nécessaires au déploiement de sa nouvelle spécificité tout en maintenant son aptitude à utiliser le saccharose comme donneur d'unité glucosyle. Dans une deuxième étude, trois variants ont été identifiés lors du criblage de la librairie semi-rationnelle sur saccharose comme présentant de nouvelles spécificités de produits. Ces mutants ont été caractérisés plus en détails, ainsi que leurs produits, sur un plan biochimique et structural. Ces mutants, appelés 37G4, 39A8 et 47A10, contiennent entre 7 et 11 mutations dans leur site actif. Il a été montré qu’ils étaient capables de reconnaitre le saccharose et le maltose (un produit de la réaction avec le saccharose) comme donneur et accepteur pour synthétiser en quantités variables de l’erlose (α-D-Glucopyranosyl-(1→4)-α-D-Glucopyranosyl-(1→2)-β-D-Fructose) et du panose (α-D-Glucopyranosyl-(1→6)-α-D-Glucopyranosyl-(1→4)-α-D-glucose), des molécules non produites par l’enzyme sauvage. Des taux de production relativement élevés ont été obtenus pour ces molécules, dont les propriétés acariogènes et le pouvoir sucrant pourraient présenter un intérêt applicatif pour l’industrie alimentaire. Dans une dernière partie, un autre mutant, appelé 30H3, a été isolé lors du criblage primaire de la librairie de par son activité élevée sur saccharose (une amélioration d’un facteur 6.5 comparé à l’enzyme sauvage). Après caractérisation, le mutant s’est avéré synthétiser un profil unique de produits en comparaison de l’enzyme sauvage ASNp. Il s’est ainsi montré très efficace pour la synthèse de maltooligosaccharides solubles, de taille de chaînes contrôlée allant d’un DP 3 à 21, et de faible polydispersité. Aucun polymère insoluble n’a été identifié. La structure 3D du mutant résolue par cristallographie des rayons X a révélé un agrandissement de la poche catalytique en raison de la présence de 9 mutations introduites dans la première sphère.... / Chemical synthesis of complex oligosaccharides still remains critical. Enzymes have emerged as powerful tools to circumvent chemical boundaries of glycochemistry. However, natural enzymes do not necessarily display the required properties and need to be optimized by molecular engineering. Combined use of chemistry and tailored biocatalysts may thus be attractive for exploring novel synthetic routes, especially for glyco-based vaccines development. The objective of this thesis was thus to apply semi-rational engineering strategies to Neisseria polysaccharea amylosucrase (NpAS), a sucrose-utilizing α-transglucosylase, in order to conceive novel substrate specificities and extend the potential of this enzyme to catalyze novel reactions, going beyond what nature has to offer. In a first study, a computer aided-approach was followed to reshape the active site of the enzyme (subsites +1, +2 and +3) for the recognition and α-1,4 glucosylation of a non-natural disaccharide acceptor molecule (allyl 2-deoxy-2-N-trichloroacetyl-β-D-glucopyranosyl-(1→2)-α-L-rhamnopyranose). The trisaccharide product is a building block for the chemo-enzymatic synthesis of oligosaccharides mimicking the repetitive units of the Shigella flexneri lipopolysaccharides, and ultimately, for the production of a vaccine against Shigellosis disease. Using computational tools dedicated to the automated protein design, combined with sequence analysis, a library of about 2.7x104 sequences was designed and experimentally constructed and screened. Altogether, 55 mutants were identified to be active on sucrose (the donor substrate), and one, called mutant F3, was subsequently found able to catalyze the α-1,4 glucosylation of the target disaccharide. Impressively, this mutant contained seven mutations in the first shell of the active site leading to a drastic reshaping of the catalytic pocket without significantly perturbing the original specificity for sucrose donor substrate. In a second study, three variants were identified from the screening of the semi-rational library on sole sucrose as displaying totally novel product specificities. They were further characterized, as well as their products, at both biochemical and structural level. These mutants, called 37G4, 39A8 and 47A10, contained between 7 and 11 mutations into their active site. They were found able to use sucrose and maltose (a reaction product from sucrose) as both donor and acceptor substrates to produce in varying amounts erlose (α-D-Glucopyranosyl-(1→4)-α-D-Glucopyranosyl-(1→2)-β-D-Fructose) and panose (α-D-Glucopyranosyl-(1→6)-α-D-Glucopyranosyl-(1→4)-α-D-glucose) trisaccharides, which are not produced at all by parental wild-type enzyme. Relatively high yields were obtained for the production of these molecules, which are known to have acariogenic and sweetening properties and could be of interest for food applications. In a last part, another mutant 30H3 was isolated due to its high activity on sucrose (6.5-fold improvement compared to wild-type activity) from primary screening of the library. When characterized, the mutant revealed a singular product profile compared to that of wild-type NpAS. It appeared highly efficient for the synthesis of soluble maltooligosaccharides of controlled size chains, from DP 3 to 21, and with a low polydispersity. No formation of insoluble polymer was found. The X-ray structure of the mutant was determined and revealed the opening of the catalytic pocket due to the presence of 9 mutations in the first sphere. Molecular dynamics simulations suggested a role of mutations onto flexibility of domain B’ that might interfere with oligosaccharide binding and explain product specificity of the mutant.
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Expression and Biochemical Characterization of Two Glucosyltransferases from Citrus paradisiDevaiah, Shivakumar P., McIntosh, Cecelia A. 12 August 2012 (has links)
Glucosylation is a common alteration reaction in plant metabolism and is regularly associated with the production of secondary metabolites. Glucosylation serves a number of roles within metabolism including: stabilizing structures, affecting solubility, transport, and regulating the bioavailability of the compounds for other metabolic processes. The enzymes that lead to glucoside formation are known as glucosyltransferases (GTs), and characteristically accomplish this task by transferring a UDP-activated glucose to a corresponding acceptor molecule. GTs involved in secondary metabolism share a conserved 44 amino acid residue motif (60–80% identity) known as the plant secondary product glucosyltransferase (PSPG) box, which has been demonstrated to include the UDP-sugar binding moiety. Among the secondary metabolites, flavonoid glycosides and limonoid glycosides affect taste characteristics in citrus making the associated glucosyltransferases particularly interesting targets for biotechnology applications in these species. The research focus of our lab is to establish the function of putative secondary product glucosyltransferase clones identified from Citrus paradisi. In the present study, we report on the activity and biochemical characterization of two clones, PGT 7 (Flavonol-3-O-GT) and PGT8 (Limonoid GT) which were expressed in Pichia pastoris.
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Control of E-cadherin Function in Cell Intercalation by ER Glucosylation Enzymes / Regulation der Funktion von E-cadherin in Zellinterkalation durch ER GlukosylierungsenzymeZhang, Yujun 11 September 2012 (has links)
No description available.
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Effects of Amino Acid Insertion on the Substrate and Regiospecificity of a Citrus paradisi GlucosyltransferaseTolliver, Benjamin M., Shivakumar, Devaiah P., McIntosh, Cecelia A. 03 April 2014 (has links)
Glucosyltransferases, or GTs, are enzymes which perform glucosylation reactions. These glucosylation reactions involve attaching a UDP-activated glucose molecule to acceptor molecules specific to the enzyme. The products of these reactions are observed to have a myriad of effects on metabolic processes, including stabilization of structures, solubility modification, and regulation of compound bioavailability. The enzyme which our lab focuses its research on is a flavonol-specific 3-O-GT found in Citrus paradisi, or grapefruit. This enzyme is part of the class of enzymes known as flavonoid GTs, which are responsible for, among other things, the formation of compounds which can affect the taste of citrus. Our lab focuses its research on performing site-directed mutagenesis on Citrus paradisi 3-O-GT in an attempt to modify its substrate specificity and regiospecificity. In this poster, we report our findings thus far concerning the addition of specific residues to the 3-O-GT's amino acid sequence based on an alignment with the sequence of a putative flavonoid GT found in Citrus sinensis.
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Effects of Amino Acid Sequence Insertion on the Substrate Preference of a Citrus Paradisi GlucosyltransferaseTolliver, Benjamin M., Shivakumar, Devaiah P., McIntosh, Cecelia A. 09 August 2013 (has links)
Glucosyltransferases (GTs) are enzymes which perform glucosylation reactions, which involve attaching a UDP-activated glucose molecule to acceptor molecules specifi c to the enzyme. The enzyme which our lab focuses its research on is a fl avonol-specifi c 3-OGT found in Citrus paradisi, or grapefruit (Cp3GT). This enzyme is part of the class of enzymes known as fl avonoid GTs, which are responsible for, among other things, the formation of compounds which can affect the taste of citrus. Our lab focuses its research on performing site-directed mutagenesis on Cp3GT in an attempt to discover the residues important for substrate and regiospecifi city. In this study, we are testing the basis of substrate septicity of Cp3GT. We hypothesize that incorporation of fi ve amino acids specifi c to Citrus sinensis GT (CsGT) into Cp3GT at 308th position may facilitate mCp3GT to use anthocyanidins as one of the substrates. We report our fi ndings thus far concerning the addition of specifi c residues to the Cp3GT’s amino acid sequence based on an alignment with the sequence of a putative fl avonoid GT found in Citrus sinensis.
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