Global ETD Search

21	Expressão heteróloga, caracterização bioquímica e avaliação da suplementação da enzima oxidativa Celobiose Desidrogenase na sacarificação da biomassa / Heterologous production, biochemical characterization and evaluation of oxidative enzyme Cellobiose Dehydrogenase in saccharification of biomass Oliva, Bianca 20 February 2019 (has links) A produção de biocombustíveis e a obtenção de alguns compostos químicos a partir de materiais renováveis, como a biomassa lignocelulósica, ainda não são processos triviais, principalmente devido a recalcitrância destes materiais. Estudos recentes reconheceram as enzimas acessórias, como xilanases e enzimas com Atividade Auxiliar, como potencializadores da atividade de celulases no processo de despolimerização da lignocelulose. A prospecção de enzimas com características termoestáveis é vantajosa para este tipo de aplicação e além disso, estudos sobre o secretoma de diversos fungos cultivados em biomassa como fonte de carbono, tem encontrado enzimas com mecanismo oxidativo, dentre eles, o fungo termofílico Myceliophthora thermophila M77. Porém, estas enzimas tem sido pouco estudadas quanto a sua aplicação na sacarificação da biomassa. Sendo assim, este trabalho visou a expressão heteróloga, a caracterização bioquímica e a ação da enzima oxidativa celobiose desidrogenase do fungo M. thermophila (M77CDH) em conjunto com outras celulases no processo de sacarificação da biomassa. Pela análise filogenética a M77CDH prospectada foi classificada como pertencente a Classe IIB das CDHs. O gene que codifica esta enzima foi clonado no vetor pEXPYR e heterólogamente expresso em A. nidulans. A proteína recombinante M77CDH foi purificada e teve sua identidade confirmada por espectrometria de massas. Nas análises bioquímicas, apresentou atividade ótima a 65 °C e reteve mais de 80% da sua atividade a 50°C por 2 horas e pela análise de dicroísmo circular apresentou um desenovelamento da sua estrutura na temperatura de transição de 62,8 °C. Apresentou mais de 80% de atividade em uma faixa ampla de pH (4,5 - 9), em que o domínio citocromo mostrou maior afinidade em pHs alcalinos, característica incomum entre as CDHs descritas na literatura. A atividade da M77CDH foi ligeiramente aumentada pela adição de MgCl2 e Na2MoO4 e altamente afetada por CuSO4 e FeCl3. A eficiência catalítica (kcat/km=266 mM-1s-1) utilizando celobiose foi bastante similar aos valores indicados por CDHs da Classe IIA. O envelope da M77CDH gerado por SAXS foi satisfatório e conveniente com a literatura. Na sacarificação de bagaço de cana pré-tratado hidrotermicamente, utilizando coquetel de A. niveus suplementado com M77CDH, foi possível observar que a adição de M77CDH modificou o perfil de produtos liberados na desconstrução da biomassa. Por fim, na sacarificação do PASC observou-se a sacarificação e produção de ácido celobiônico. / The production of biofuels and chemicals from renewable materials such as lignocellulosic biomass are non-trivial processes mainly due to the recalcitrance of the material. Recent studies have recognized accessory enzymes such as xylanases and Auxiliary Activity enzymes as potentiators in cellulase activity during the depolymerization of lignocellulose. The prospection of thermostable enzymes can be an advantage the improve the depolymerization of these materials. In addition, several enzymes showing oxidative mode of action were found in the secretoma of the thermophilic fungus Myceliophthora thermophila strain M77. However, these enzymes are poor studied regarding their application in biomass saccharification. Therefore, this project aimed the heterologous expression and biochemical characterization of the oxidative enzyme cellobiose dehydrogenase of the fungus M. thermophila (M77CDH). By phylogenetic analysis the M77CDH was classified as belonging to Class IIB of CDHs. The gene encoding this enzyme was cloned and heterologously expressed in A. nidulans, the M77CDH was purified and had its identity confirmed by mass spectrometry. In the biochemical analyzes the M77CDH showed an optimum activity at 65 °C and retained more than 80% of its activity at 50 °C for 2 hours. The circular dichroism analysis showed a denaturation of its structure at the transition temperature of 62.8 ° C. M77CDH also kept more than 80% of its activity in a wide pH range (4.5 - 9), in which the cytochrome domain showed higher affinity at alkaline pH, an unusual behavior compared with other CDHs described in the literature. The activity of M77CDH was increased slightly in the presence of MgCl2 and Na2MoO4 and was highly affected by CuSO4 and FeCl3. The catalytic efficiency (kcat/km = 266 mM-1s-1) in cellobiose was quite similar to the values indicated by CDHs from Class IIA. The envelope of M77CDH generated by SAXS was satisfactory and convenient with the literature. In saccharification of sugarcane bagasse hydrothermally pretreated using A. niveus cocktail supplemented with M77CDH was possible to observe the addition of M77CDH modified the profile of released products in the deconstruction of the biomass. Finally, in the action on PASC was observed the saccharification and production of cellobionic acid. Biomass Biomassa Caracterização Cellobiose Dehydrogenase Celobiose Desidrogenase Characterization Expressão heteróloga Heterologous expression Myceliophthora thermophila Myceliophthora thermophila Sacarificação Saccharification
22	Structural studies on the extracellular flavocytochrome cellobiose dehydrogenase from <i>Phanerochaete chrysosporium</i> Hällberg, Martin January 2002 (has links) <p>Microorganisms that degrade lignocellulose play an important role in maintaining the global carbon cycle. Under cellulolytic conditions, the fungus <i>Phanerochaete chrysosporium</i> produces an extracellular flavocytochrome, cellobiose dehydrogenase (CDH), with a proposed role in lignocellulose degradation. CDH consists of 755 amino acids including a C-terminal flavodehydrogenase linked by a peptide hinge to an N-terminal <i>b</i>-type cytochrome. The enzyme catalyses the oxidation of cellobiose to cellobiono-1,5-lactone, followed by transfer of electrons to an electron acceptor, either directly by the flavodehydrogenase domain, or via the cytochrome domain. This thesis presents a structural study on the individual domains of <i>P. chrysosporium</i> cellobiose dehydrogenase.</p><p>The crystal structure of the cytochrome was determined at 1.9 Å resolution. It folds as a β-sandwich with the topology of the antibody Fab V(H) domain, and the haem iron is ligated by Met65 and His163. This is only the second example of a <i>b</i>-type cytochrome with this ligation. The haem propionates are surface exposed to facilitate interdomain electron transfer.</p><p>The structure of a cytochrome Met65His mutant was determined at 1.9 Å resolution. In the mutant, the iron is ligated by the histidyl δ and ε nitrogens, rather than the usual N-ε/N-εligation. This is the first example of a <i>bis</i>-His N-ε/N-δ coordinated protoporphyrin IX iron. The structure of the flavoprotein domain was determined at 1.5 Å resolution. It is partitioned into an FAD-binding subdomain of α/β-type and a substrate-binding subdomain consisting of a seven-stranded β-sheet and six α-helices. Furthermore, the structure of the flavoprotein with the inhibitor cellobiono-1,5-lactam at 1.8 Å resolution lends support to a hydride-transfer mechanism for the reductive-half reaction of CDH although a radical mechanism cannot be excluded.</p> Cell and molecular biology cellobiose dehydrogenase flavocytochrome hydride transfer radical mechanism X-ray crystallography Cell- och molekylärbiologi Cell and molecular biology Cell- och molekylärbiologi
23	Structural studies on the extracellular flavocytochrome cellobiose dehydrogenase from Phanerochaete chrysosporium Hällberg, Martin January 2002 (has links) Microorganisms that degrade lignocellulose play an important role in maintaining the global carbon cycle. Under cellulolytic conditions, the fungus Phanerochaete chrysosporium produces an extracellular flavocytochrome, cellobiose dehydrogenase (CDH), with a proposed role in lignocellulose degradation. CDH consists of 755 amino acids including a C-terminal flavodehydrogenase linked by a peptide hinge to an N-terminal b-type cytochrome. The enzyme catalyses the oxidation of cellobiose to cellobiono-1,5-lactone, followed by transfer of electrons to an electron acceptor, either directly by the flavodehydrogenase domain, or via the cytochrome domain. This thesis presents a structural study on the individual domains of P. chrysosporium cellobiose dehydrogenase. The crystal structure of the cytochrome was determined at 1.9 Å resolution. It folds as a β-sandwich with the topology of the antibody Fab V(H) domain, and the haem iron is ligated by Met65 and His163. This is only the second example of a b-type cytochrome with this ligation. The haem propionates are surface exposed to facilitate interdomain electron transfer. The structure of a cytochrome Met65His mutant was determined at 1.9 Å resolution. In the mutant, the iron is ligated by the histidyl δ and ε nitrogens, rather than the usual N-ε/N-εligation. This is the first example of a bis-His N-ε/N-δ coordinated protoporphyrin IX iron. The structure of the flavoprotein domain was determined at 1.5 Å resolution. It is partitioned into an FAD-binding subdomain of α/β-type and a substrate-binding subdomain consisting of a seven-stranded β-sheet and six α-helices. Furthermore, the structure of the flavoprotein with the inhibitor cellobiono-1,5-lactam at 1.8 Å resolution lends support to a hydride-transfer mechanism for the reductive-half reaction of CDH although a radical mechanism cannot be excluded. Cell and molecular biology cellobiose dehydrogenase flavocytochrome hydride transfer radical mechanism X-ray crystallography Cell- och molekylärbiologi Cell and molecular biology Cell- och molekylärbiologi
24	Evolution Of New Metabolic Functions By Mutations In Pre-Existing Genes : The chb Operon Of Escherichia Coli As A Paradigm Kachroo, Aashiq Hussain 02 1900 (has links) Escherichia coli has the ability to respond to stress such as starvation in a very efficient manner. Under conditions of starvation wherein a novel substrate is provided as a sole nutritional source, Spontaneous mutants arise in a population of E.Coli that are able to utilize this novel carbon Many generic systems, upon mutational activation, have been shown to allow E.coli to Grow on novel substrates. . Wildtype E.coli is not able to utilize cellobiose, a disaccharide of glucose, as a carbon source. However after prolonged incubation with cellobiose as a sole carbon source, spontaneous Cel+ mutants can be isolated. The Cel+ derivatives have mutations in the chb operon involved in the utilization of N-N-diacetylchitobiose, a disaccharide of N-acetyl glucosamine. The chb operon of E.coli is comprised of six ORFs (chbBCARFG) with a ~200bp regulatory region (chbOP); chbBCA encode the IIB, IIC and IIA domains of the PTS-dependent permease respectively, chbR encodes for a dual function activator/repressor, chbF encodes the phopho-chitobiase and chbG codes for a protein of unknown function. It has been shown that the three proteins ChbR, CAP and NagC regulate the expression of the chb operon. ChbR along with CAP activates the chb operon in the presence of chitobiose. In the absence of the inducer, ChbR, along with NagC, represses the chb operon. Activation of the chb operon allowing utilization of cellobiose was earlier shown to occur either via insertion of IS1, IS2 or IS5 into the regulatory region (chbOP) upstream of the transcription start site or by base substitutions in chbR. Comparison of the chb operon sequence obtained from various Cel+ mutants with E.coli K12 genome sequence showed many differences. These differences were clustered in both the permease (chbBCA) as well as the enzyme (chbF) of the chb operon, suggesting that mutations are needed in all the ORFs of this operon in order to alter the specificity of E.coli towards utilization of cellobiose. The main objective of this thesis is to elucidate the mechanism of mutational activation of the chb operon of E.coli to allow utilization of cellobiose. These studies have shown that two classes of mutations, those that abrogate repression by NagC and those that alter the regulation by ChbR, together are necessary and sufficient to confer a Cel+ phenotype to E.coli. These studies also show that the wildtype permease and phospho-â -glucosidase are able to recognize and cleave cellobiose. Initial experiments were designed to study the role of independent mutational events of either insertion within the regulatory region or loss-of-function of chbR in conferring E.coli a Cel+ phenotype. The single mutational event of either the insertion within the regulatory region chbOP that disrupts the strong NagC binding site (mimicking an IS element) or knockout of chbR did not confer on E.c oli a Cel+ phenotype. However the presence of the artificial insertion within chbOP accelerated the process of obtaining Cel+ mutants suggesting a positive role for insertion elements. The apparent inability of the chbR knockout strain to mutate to Cel+ suggested that chbR is essential for acquisition of a Cel+ phenotype. Reporter gene assays showed that the presence of an insertion within chbOP enhances the promoter activity marginally. The role of chbR as a repressor was further ascertained by increased promoter activity seen from wildtype chbOP-lacZ fusion in a chbR knockout strain. A marginal enhancement in promoter activity in the presence of cellobiose in a strain carrying a wildtype chbR as compared to chbR knockout strain suggested an additional positive role of chbR. The inability of cellobiose to produce an inducing signal necessary for activation by wildtype ChbR protein suggested that gain-of-function mutations within chbR locus might play a crucial role in acquisition of cellobiose utilization phenotype by E.coli. The chbR clones obtained from various Cel+ mutants could activate transcription from the chb promoter at a higher level in the presence of cellobiose. However this activation was seen only in a strain carrying disruptions of the chromosomal nagC and chbR loci. These transformants also showed a Cel+ phenotype on the MacConkey cellobiose medium suggesting that the wildtype permease and enzyme upon induction could recognise, transport and cleave cellobiose, respectively. This was confirmed by cloning the wildtype genes encoding the permease and phospho-â -glucosidase under a heterologous promoter (Plac). The wildtype E.coli strain transformed with a plasmid carrying the genes could utilize cellobiose efficiently. Large scale isolation of Cel+ mutants was undertaken. Variation in the ability of cellobiose utilization was observed among the different mutants. Several Cel+ mutants retained the ability to utilize chitobiose. Cel+ mutants lacking insertions within chbOP contained a loss-of-function mutation at the nagC locus. The sequencing of the chbR locus from Cel+ mutant strains showed a single basepair change at the DNA level translating into a single amino acid change when compared to the Cel- counterpart. Nucleotide sequence of chbR obtained from two Cel+ natural isolates of E.coli also showed a single base mutation. The chbR clones from the two mutants, when transformed into a strain carrying disruptions at the chromosomal nagC and chbR loci, conferred it a Cel+ phenotype. Initial characterization of one of the mutant ChbR (N238S) was carried out. Reporter assays in a strain containing a wildtype copy of chbR at the genomic locus and a disruption of nagC showed that the wildtype ChbR is dominant over the mutant ChbR (N238S). The biochemical investigations of the wildtype and mutant ChbR (N238S) were undertaken. Wildtype ChbR showed non-specific binding to chbOP that could not be competed out by excess cold DNA. DNaseI protection assays confirmed that wildtype ChbR formed a relatively nonspecific complex with chbOP as compared to mutant ChbR (N238S). Finally DNaseI footprinting experiments showed that mutant ChbR (N238S) binds the specific direct repeat within chbOP better than the wildtype protein. These results indicated that mutant ChbR (N238S) has lost its ability to repress transcription by its inability to bind chbOP non-specifically. In addition, the mutant ChbR (N238S) has acquired the ability to activate transcription in the presence of cellobiose. This could be partly mediated via enhanced binding of the mutant ChbR (N238S) to the specific DNA binding site within chbOP in contrast to its wildtype counterpart. To conclude, this work has shown that acquisitive evolution of E.coli towards utilization of cellobiose in laboratory conditions alters the regulation of the chb operon and allows it to acquire new metabolic capability for utilizing cellobiose under selective pressure. Metabolic Functions Mutation Genetics Escherichia Coli Cellobiose-positivie Mutants Chitobiose (Chb) Operon Gene-Regulation ChbR N238S Genetics
25	Matériaux à porosité contrôlée sulfonés : Synthèse, Caractérisation, Etude des propriétés catalytiques Karaki, Mariam 08 July 2013 (has links) (PDF) La catalyse solide acide a été pendant longtemps l'objet d'activité de recherche intense, en particulier pour l'industrie pétrochimique. Aujourd'hui, les catalyseurs solides acides sont de plus en plus étudiés dans d'autres domaines et en particulier dans celles liées à la "chimie verte" et à la valorisation des bioressources, telles que la synthèse de biodiesel et la transformation des polysaccharides. L'objectif de la thèse est d'étudier le potentiel des matériaux poreux sulfonés ayant une porosité contrôlée dans des réactions catalysées par un acide en condition eau surchauffé telle que l'hydrolyse de la cellobiose. Dans une première partie, nous décrivons la préparation et la caractérisation des organosilicates mésoporeux périodiques sulfonés de type SBA-15, SBA-1 et KIT-6 par co-condensation de 1,4-bis (triéthoxysilyl) benzène (BTEB). Les matériaux ont été acidifiés suivant des voies différentes à l'aide de 3-mercaptopropyltriméthoxysilane (MPTMS)/H2O2 ou d'acide chlorosulfonique (ClSO3H). Leur propriété acide a été étudiée par adsorption d'NH3 suivie par calorimétrie et par la réaction de déshydratation d'isopropanol (IPA) comme réaction modèle en phase gazeuse. Contrairement à notre attente, l'adsorption d'NH3 suivie par calorimétrie a mis en évidence l'hétérogénéité de la force des sites suggérant la présence de sites distincts de la sulfonation. Les solides sulfonés avec l'acide chlorosulfonique ont une activité équivalente à celle de la résine sulfonée, Amberlyst 15, mais ils sont moins stables en raison de la libération des espèces de soufre. Les catalyseurs préparés en utilisant un groupement mercapto-propyle suivie d'une oxydation sont moins acides et ils ont donné des niveaux d'activité plus basse dans la réaction de déshydratation d'IPA. Pour l'hydrolyse de la cellobiose, de bonnes performances ont été obtenues à 150°C, mais, ces matériaux se sont montrés instables dans des conditions hydrothermales avec une lixiviation totale de soufre réalisant alors la réaction en phase homogène. Un lavage dans l'eau surchauffée des matériaux contenant des groupements propyles-SO3H conduit à une diminution de leur efficacité dans l'hydrolyse de la cellobiose, mais un gain de stabilité a été obtenu, permettant le recyclage de ces matériaux. Dans une deuxième partie, des répliques carbonées sulfonées par l'acide chlorosulfonique ou l'acide sulfurique ont été synthétisé. La sulfonation par l'acide sulfurique suivi par un lavage dans l'eau bouillante puis un prétraitement thermique à 300°C sous azote, de ces matériaux aboutissent au meilleur catalyseur en termes d'activité/stabilité. [CHIM:OTHE] Chemical Sciences/Other [CHIM:OTHE] Chimie/Autre Répliques carbonées sulfonées Hydrolyse de la cellobiose Déshydratation d'isopropanol Catalyseur solide acide Stabilité hydrothermale
26	The kinetics of cellulose enzymatic hydrolysis : Implications of the synergism between enzymes Väljamäe, Priit January 2002 (has links) <p>The hydrolysis kinetics of bacterial cellulose and its derivatives by <i>Trichoderma reesei</i> cellulases was studied. The cellulose surface erosion model was introduced to explain the gradual and strong retardation of the rate of enzymatic hydrolysis of cellulose. This model identifies the decrease in apparent processivity of cellobiohydrolases during the hydrolysis as a major contributor to the decreased rates. Both enzyme-related (non-productive binding) and substrate-related (erosion of cellulose surface) processes contribute to the decrease in apparent processivity. Furthermore, the surface erosion model allows, in addition to conventional endo-exo synergism, the possibility for different modes of synergistic action between cellulases. The second mode of synergism operates in parallel with the conventional one and was found to be predominant in the hydrolysis of more crystalline celluloses and also in the synergistic action of two cellobiohydrolases. </p><p>A mechanism of substrate inhibition in synergistic hydrolysis of bacterial cellulose was proposed whereby the inhibition is a result of surface dilution of reaction components (bound cellobiohydrolase and cellulose chain ends) at lower enzyme-to-substrate ratios. </p><p>The inhibition of cellulases by the hydrolysis product, cellobiose, was found to be strongly dependent on the nature of the substrate. The hydrolysis of a low molecular weight model substrate, such as para-nitrophenyl cellobioside, by cellobiohydrolase I is strongly inhibited by cellobiose with a competitive inhibition constant around 20 μM, whereas the hydrolysis of cellulose is more resistant to inhibition with an apparent inhibition constant around 1.5 mM for cellobiose.</p> Biochemistry Acetobacter Cellobiohydrolase Cellobiose Cellulase Cellulose Diffusion Endoglucanase Hydrolysis Inhibition Kinetics Model Product Substrate Surface Synergism Trichoderma reesei Biokemi Biochemistry Biokemi
27	The kinetics of cellulose enzymatic hydrolysis : Implications of the synergism between enzymes Väljamäe, Priit January 2002 (has links) The hydrolysis kinetics of bacterial cellulose and its derivatives by Trichoderma reesei cellulases was studied. The cellulose surface erosion model was introduced to explain the gradual and strong retardation of the rate of enzymatic hydrolysis of cellulose. This model identifies the decrease in apparent processivity of cellobiohydrolases during the hydrolysis as a major contributor to the decreased rates. Both enzyme-related (non-productive binding) and substrate-related (erosion of cellulose surface) processes contribute to the decrease in apparent processivity. Furthermore, the surface erosion model allows, in addition to conventional endo-exo synergism, the possibility for different modes of synergistic action between cellulases. The second mode of synergism operates in parallel with the conventional one and was found to be predominant in the hydrolysis of more crystalline celluloses and also in the synergistic action of two cellobiohydrolases. A mechanism of substrate inhibition in synergistic hydrolysis of bacterial cellulose was proposed whereby the inhibition is a result of surface dilution of reaction components (bound cellobiohydrolase and cellulose chain ends) at lower enzyme-to-substrate ratios. The inhibition of cellulases by the hydrolysis product, cellobiose, was found to be strongly dependent on the nature of the substrate. The hydrolysis of a low molecular weight model substrate, such as para-nitrophenyl cellobioside, by cellobiohydrolase I is strongly inhibited by cellobiose with a competitive inhibition constant around 20 μM, whereas the hydrolysis of cellulose is more resistant to inhibition with an apparent inhibition constant around 1.5 mM for cellobiose. Biochemistry Acetobacter Cellobiohydrolase Cellobiose Cellulase Cellulose Diffusion Endoglucanase Hydrolysis Inhibition Kinetics Model Product Substrate Surface Synergism Trichoderma reesei Biokemi Biochemistry Biokemi
28	Exploring the Evolution of Cellobiose Utilization in Shigella Sonnei And the Conservation of ChbG Orthologs in Eukaryotes Joseph, Asha Mary January 2016 (has links) (PDF) The chb operon constitutes the genes essential for utilization of chitooligosaccharides in Escherichia coli and related species. The six genes of the operon code for a transcriptional regulator (ChbR) of the operon, a permease (ChbBCA), a monodeacetylase (ChbG), and a phospho-beta-glucosidase (ChbF). In the absence of the substrate, the operon is maintained in a transcriptionally repressed state, while presence of the substrate leads to transcriptional activation. Regulation of the chb operon is brought about by the concerted action of three proteins, the negative regulator NagC coded by the nag operon, the dual function regulator ChbR coded by the chb operon and the universal regulatory protein CRP. Mutations that lead to alterations in the regulation of the operon can facilitate utilization of cellobiose, in addition to chitooligosaccharides by E. coli. The studies presented in Chapter II were aimed at understanding the evolution of cellobiose utilization in Shigella sonnei, which is phylogenetically very close to E. coli. Cel+ mutants were isolated from a Cel- wild type S. sonnei strain. Interestingly, Cel+ mutants arose relatively faster on MacConkey cellobiose agar from the S. sonnei wild type strain compared to E. coli. Similar to E. coli, the Cel+ phenotype in S. sonnei mutants was linked to the chb operon. Deletion of the phospho-β-glucosidase gene, chbF also resulted in loss of the Cel+ phenotype, indicating that ChbF is responsible for hydrolysis of cellobiose in these mutants. Previous work from the lab has shown that acquisition of two classes of mutations is necessary and sufficient to give rise to Cel+ mutants in E. coli. The first class of mutations either within the nagC locus or at the NagC binding site within the chb promoter, lead to NagC derepression. The second class consisting of gain-of-function mutations in chbR enable the recognition of cellobiose as an inducer by ChbR and subsequent activation of the operon. However, in S. sonnei a single mutational event of an IS element insertion resulted in acquisition of this phenotype. Depending on the type and location of the insertion, the mutants were grouped as Type I, and Type II. In Type I mutants an 1S600 insertion between the inherent -10 and -35 elements within the chb promoter leads to ChbR-independent constitutive activation of the operon, while in Type II mutants, an IS2/600 insertion at -113/-114, leads to ChbR-dependent, cellobiose-inducible expression of the operon. The results presented also indicate that in addition to relieving NagC mediated repression, the insertion in Type II mutants also leads to increase in basal transcription from the chb promoter. Constitutive expression of the chb operon also results in utilization of the aromatic β-glucosides salicin and arbutin, in addition to cellobiose in Type I mutants, which indicates the promiscuous nature of permease and hydrolysis enzyme of the chb operon. This part of the thesis essentially demonstrates the different trajectories taken for the evolution of new metabolic function under conditions of nutrient stress by two closely related species. It emphasizes the significance of the strain background, namely the diversity of transposable elements in the acquisition of the novel function. The second part of this research investigation, detailed in Chapter III deals with experiments to characterize the eukaryotic orthologs of the last gene of the chb operon. The chbG gene of E. coli codes for a monodeacetylase of chitooligosaccharides like chitobiose and chitotriose. The protein belongs to a highly conserved, but less explored family of proteins called YdjC, whose orthologs are present in many prokaryotes and eukaryotes including mammals. The human YDJC locus located on chromosome 22 is linked to a variety of inflammatory diseases and the transcript levels are relatively high in stem cells and a few cancer cells. In silico analysis suggested that the mammalian YdjC orthologs possess sequence and structural similarity with the prokaryotic counterpart. The full length mouse YdjC ortholog, which is 85% identical to the human ortholog was cloned into a bacterial vector and expressed in a chbG deletion strain of E. coli. The mouse YdjC ortholog could neither promote growth of the strain on chitobiose nor induce transcription from the chb promoter. The purified mouse YdjC ortholog could not deacetylate chitobiose in vitro as well, suggesting that the mouse ortholog failed to complement the function of the E. coli counterpart, ChbG under the conditions tested in this study. In order to characterize the mammalian YdjC orthologs more elaborately, further experimentation was performed in mammalian cell lines. The results indicate that YdjC is expressed in mammalian cell lines of different tissue origin and the expression was seen throughout the cell. Overexpression of mouse Ydjc in a few mammalian cells also resulted in increased proliferation and migration, indicating a direct or indirect role of this protein in cell growth/proliferation. The mammalian orthologs of ChbG therefore appear to have related but distinct activities and substrates compared to the bacterial counterpart that need to be elucidated further. Gene Regulation Chitibiose Operons Escherichia Coli Mutalian Genetics Shigella sonnei Cellobiose Eukaryotic ChbG Orthologs Bacterial Genes Glucosides Bacterial Genetics chb Operon S. sonnei Molecular Biology
29	Synthèse de copolymères greffés d'acétate de cellulose-g-PS par polymérisation radicalaire contrôlée par les nitroxydes / Synthesis of graft copolymers cellulose acetate-g-PS by Nitroxide-Mediated Polymerization Moreira, Guillaume 19 June 2014 (has links) Face à la diminution croissante des ressources d'origine fossile, une attention particulière est portée depuis plusieurs années envers l'utilisation de ressources renouvelables. Dans ce contexte, beaucoup de recherches sont orientées vers l'utilisation de polysaccharides tels que la cellulose. L'intérêt de ces composés est qu'ils sont abondants, peu chers et biodégradables. A l'inverse, ces polymères possèdent une faible résistance mécanique limitant ainsi leurs applications. De manière à moduler les propriétés de ces polymères, une alternative consiste à les modifier chimiquement par greffage de chaînes de polymères synthétiques. Néanmoins, les stratégies de greffage décrites dans la littérature présentent certaines limitations notamment sur la facilité de mise en oeuvre, la toxicité des méthodes employées, le nombre d'étapes de synthèses ou encore le contrôle des masses molaires. Par ailleurs, la caractérisation de ces architectures complexes reste délicate notamment pour prouver le greffage covalent des chaînes de polymère sur le polysaccharide. C'est précisément dans cet axe de recherche que s'insère ce sujet de thèse. Plus particulièrement, l'objectif principal consiste à mettre au point une méthode de greffage de l'acétate de cellulose robuste et facile à mettre en oeuvre, en vue d'une utilisation potentielle en tant que compatibilisant de mélange de polystyrène et d'acétate de cellulose. Afin d'atteindre cet objectif, notre stratégie a consisté à utiliser la polymérisation radicalaire contrôlée par les nitroxydes (NMP) où une attention particulière a été portée sur la caractérisation structurale des matériaux synthétisés (RMN du solide et DOSY, RPE, CES, DLS et DSC). / In order to respond to the fossil resources depletion, a particular attention was paid to the use of renewable resources since several years. In this context, many researches focus on the use of polysaccharides such as cellulose. These compounds are attractive because of their abundance, low cost and biodegradability. On the other hand, these polymers suffer from weak mechanical resistance limiting their practical applications. Grafting synthetic polymers chains on these natural polymers is an alternative to this problem. Nevertheless, grafting strategies described in the literature involve certain limitations such as the difficulty of implementation, the toxicity of the used methods, the great number of synthesis steps or the control of molar mass. Moreover, the characterization of these complex architectures remains delicate in order to prove the covalent grafting of chains on the polysaccharide. In line with this research context, the topic of this thesis concerns the development of a robust method for cellulose acetate polymer grafting. Moreover, the selected method has to be easy to implement, with a possible application as a compatibilizer for blending of polystyrene and cellulose acetate. In order to achieve this purpose, our strategy is based on the use of Nitroxide-Mediated Polymerization (NMP) where particular attention was paid to the structural characterization of synthesized materials (solid state NMR, DOSY NMR, ESR, SEC of grafts, DLS and DSC). Acétate de cellulose D-Glucose D-Cellobiose Polystyrène Nitroxyde Sg1 BlocBuilder® Alcoxyamine Ea D Acroylation 1 2-Ira. Cellulose acetate D-Glucose D-Cellobiose Polystyrene Nitroxide-Mediated polymerization Nitroxide Sg1 BlocBuilder® Alkoxyamine Ea D Acroylation 1 2-Ira.
30	Regulation of Chitin Oligosaccharides Utilization in Escherichia Coli Verma, Subhash Chandra January 2013 (has links) (PDF) The genome of Escherichia coli harbors several catabolic operons involved in the utilization of a wide variety of natural compounds as carbon sources. The chitobiose (chu) operons of E.coli Is involved in the utilization of chitobiose(disaccharide of N-acety1-D-glucosamine) and cellbiose (disaccharide of glucose) derived from the two most abundant naturally occurring carbon sources on earth, chitin and cellulose respectively. The operon consists of the chbBCARFG genes coding for transport, regulation and hydrolysis functions required to utilize these compounds; the chuyBCA genes code for a multi-subuni PTS transporter ; the chuR codes for a dual function repressor/activator of the operon; the chbF codes for a phospho-glucosidase and the chbG codes for a protein of unknown function. The chu operon Is regulated by three transcription factors; NagC, a key regulator of the nag genes involved in amino sugar metabolism; ChbR, a dual function operon-specific regulator; and CRP_cAMP. The operon is repressed by NagC and ChbR in the absence of catabolic substrate. In the presence of chitobiose, expression is induced by the abrogation of NagC-mediated repression by GlcNAc-6-P generated by the hydrolysis of chitobiose-6-P and subsequent activation of transcription by ChbR and CPR-cAMP. Wild type E.coli connot utilize cellbiose due to the inability of cellbiose to induce expression from the operon. The simultaneous presence of a loss of function mutation in nagC and a gain –of-function mutation in chbR is necessary and sufficient to allow cellbiose to induce expression and confer on E.coli the ability to utilize cellbiose. The activation step by ChbR and CPR-cAMP requires an inducer that is recognized by ChbR. The chemical identity of the inducer and the mechanism of transcriptional activation by ChbR and CPR-cAMP are not understood. The studies described in the chapter 2 shows that chbG is essential for the utilization of the acetylated sugars chitobiose and chitotriose while it is dispensable for the sugars lacking the acety1group such as cellobiose and chitosan dimer, a disaccharide of N-glucosamine. ChbG is produced as a cytosolic protein and removes one acety1 group from chitobiose and chitotriose thus shows a mono-decetylase activity. Taken together, the observing suggest that ChbG deacetylates chitobiose-6-P and chitotriose-6-P producing the mono-decetylated from of the sugars. The deacetylateion is necessary for their recognition both as inducers by ChbR to activate transcription along with CRP-cAMP and as substractes by phosop-glucosidase ChbF. Cellobiose positive(Cel+) mutants carrying nagC delection and different gain-of-function mutations in chbR are independent of chbG for induction by chitobiose suggesting that the mutations in ChbR can allow it to recognize the acetylated form of chitobiose-6-P. Despite normal induction, the mutants to grow on chitobiose without chbG are consistant with the requirement of deacetylation for hydrolysis by ChbF. The prediction active site of chbG was validated by demonstrating the loss of chbG function upon alanine substitution of the putative metal binding residues. Vibro cholerace ChbG can complement the function of E.coli ChbG indicating that ChbG is conserved in both the organisms. The studies presented in chapter 3 address the mechanism of transcriptional activation of the chb operon by ChbR and CPR-cAMP. ChbR and CPR-cAMP function in a synergistic manner in response to the induction signal. The synergy is not because of their cooperative binding to the DNA. The role of CRP as a class I activator via the known mechanism involving interaction between the Activation region1 (AR1) and the C-terminal domain of the alpha subunit of RNA polymerase (CTD) was not crucial for the chb operon. A direct interaction between the two activators in virto was observed. Based on these results and the close spacing of the synergy is due to interaction between the two regulators bound to DNA that is enhanced in the presence of the inducer, binding about an optimal confirmation in ChbR required to interact with RNA polymerase. ChbR contacts different residues in the subunit in response to cellbiose and chitobiose; whereas it utilizes the known residues in the presence cellbiose, it appears to require different and unknown residues for induction in the presence of chitobiose. In conclusion, the studies reported in chapter 2 and 3 provide an understanding of the regulation of the chitin oligosaccharides utilization in E.coli at different levels. The broad implications of these studies and possible future directions are discussed in chapter 4. ChbG is an evolutionary conserved protein found in both prokaryotes and enkayotes including humans. ChbG homologs have been implicated in inflammatory bowel disorders in humans and development in metazoans. Therefore, the studies on chbG described in this thesis have been broader significance. Escherichia Coli Bacteria - Chitiobiose Utilization Escherichia - Chitin Oligosaccharides Chitobiose Operons (chb) Gene Escherichia Coli Chitobiose Operons Carbohydrate Metabolism chb Operon chbG E. coli - Chitin Oligosaccharides Molecular Biology

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