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41	Produção e caracterização bioquímica de uma nova transglutaminase microbiana = Production and biochemical characterization of a new microbial transglutaminase / Production and biochemical characterization of a new microbial transglutaminase Melo, Ricardo Rodrigues de, 1985- 08 June 2013 (has links) Orientador: Hélia Harumi Sato / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia de Alimentos / Made available in DSpace on 2018-08-22T23:52:05Z (GMT). No. of bitstreams: 1 Melo_RicardoRodriguesde_M.pdf: 1621799 bytes, checksum: 14182717e9ba5de8c1d5014f330c1b6c (MD5) Previous issue date: 2013 / Resumo: Transglutaminase é uma enzima capaz de catalisar a formação de ligações cruzadas intra- e intermoleculares entre proteínas, peptídeos e aminas primárias por meio de ligações covalentes entre resíduos de lisina e glutamina. Desta forma, transglutaminase pode ser utilizada em diversos setores industriais para o desenvolvimento de novos produtos ou para a modificação de suas características. A linhagem B6 isolada de amostra de solo coletada na região do Estado de Minas Gerais foi identificada como tendo características morfológicas típicas de actinomicetos e pela análise da região 16S rRNA há colocou na subclasse Streptomyces próximo a linhagem Streptomyces angustmycinicus NBRC 3934T. A fim de aumentar a produção de transglutaminase (2,75 U/mL) pela linhagem Streptomyces sp. B6, o meio de fermentação foi submetido a processos de otimização. Como primeiro passo da otimização, o crescimento do micro-organismo e a produção da enzima foram estudados através de uma pré-seleção de fontes de carbono, nitrogênio e sais no meio de produção. Após as análises das diferentes fontes, um delineamento experimental do tipo Plackett-Burman foi utilizado para a seleção dos componentes do meio de cultivo que afetam a produção de transglutaminase. Os resultados do delineamento experimental indicaram que a produção de transglutaminase foi influenciada negativamente pela peptona bacteriológica e MgSO4.7H2O, positivamente pelo amido de batata, glicose, peptona de caseína e KH2PO4.7H2O e não foi influenciada pelo farelo de soja, considerando um nível de confiança de 95%. A concentração de amido de batata foi fixada no maior nível testado no planejamento Plackett-Burman devido à gelificação do meio de fermentação em concentrações maiores. Assim, os três fatores que influenciaram a produção de transglutaminase (glicose, peptona de caseína e KH2PO4.7H2O) foram otimizados para obter o máximo de produção da enzima utilizando delineamento composto central. Sob a condição otimizada, a qual continha 25 g/L de farinha de soja, 35 g/L de amido de batata, 5 g/L de glicose, 24,5 g/L de peptona de caseína e 8 g/L de KH2PO4.7H2O, a atividade enzimática atingiu 6,13 U/mL, apresentando 125% à mais de atividade em relação á obtida no meio antes da otimização. A transglutaminase microbiana produzida pela linhagem Streptomyces sp. B6 exibiu atividade ótima em 45°C e em pH de 6,5 e 11,0. A enzima manteve-se estável na faixa de pH 3,0-11,0 durante 60 minutos à 40°C durante 3 horas. A transglutaminase não foi inibida por Ca2+, Na+, Co2+, Mn2+, K+, Mg2+, Ba2+, EDTA, L-cisteína e glutationa na concentração de 5 mM, mas foi inibida na presença de Hg2+, Cu2+, Zn2+ e Fe2+ na concentração de 5mM. A linhagem Streptomyces sp. B6 é uma nova fonte de transglutaminase com características interessantes para aplicações biotecnológicas / Abstract: Transglutaminase is an enzyme capable of catalyzing the forming intra-and intermolecular cross-linking between proteins, peptides and primary amines by covalent bonds between lysine and glutamine residues. Thus, transglutaminase can be used in food processing industries to develop new products and modify their characteristics. The B6 strain was isolated from soil sample collected in the region state of Minas Gerais was identified as having morphological characteristics typical of the actinomycetes, and the 16S rRNA analysis placed it in the Streptomyces subclade, closely related to Streptomyces angustmycinicus NBRC 3934T. In order to increase the transglutaminase production (2.75 U/mL) from Streptomyces sp. B6 strain, the fermentation medium was subjected to optimization processes. In the first step of optimization, the micro-organism growth and enzyme production were studied through a pre-selection of carbon, nitrogen and salts sources in the culture medium. After analysis of different sources, the Plackett¿Burman experimental design was used for screening the components of the culture medium that affect the transglutaminase production. Results of the experiment indicated that production of transglutaminase was negatively influenced by bacteriological peptone and MgSO4.7H2O, positively influenced by potato starch, glucose, casein peptone and KH2PO4.7H2O and was not influenced by soybean meal, considering 95% of confidence level. The potato starch concentration was fixed at the highest level tested in Plackett¿Burman design due to gelation of the fermentation medium in higher concentrations. Thus, the three factors that influence the transglutaminase production (glucose, casein peptone and KH2PO4.7H2O concentrations) were optimized to obtain the maximum transglutaminase production using central composite design. Under the proposed optimized condition, which contained 25 g/L soybean meal, 35 g/L potato starch, 5 g/L glucose, 24.5 g/L casein peptone and 8 g/L KH2PO4.7H2O, the enzyme activity reached 6.13 U/mL, which was 125% more than the activity in relative obtained medium before optimization. The microbial transglutaminase produced by Streptomyces sp. B6 strain exhibited optimal activity at 45 oC and at pH 6.5 and 11.0. The enzyme remained stable in the pH range from 3.0 - 11.0 for 60 minutes and at 40 oC temperature for 3 hours. The transglutaminase was not inhibited by Ca2+, Na+, Co2+, Mn2+, K+, Mg2+, Ba2+, EDTA, L-cysteine and glutathione in concentration 5 mM, but was inhibited in the presence of Hg2+, Cu2+, Zn2+ and Fe2+ in concentration 5 mM. In conclusion, Streptomyces sp. B6 strain is a new source of transglutaminase with interesting features for biotechnological applications / Mestrado / Ciência de Alimentos / Mestre em Ciência de Alimentos Transglutaminase microbiana Streptomyces sp. - Caracterização Delineamento de Experimentos Classificação Isolamento Microbial transglutaminase Streptomyces sp. - Characterization Design of experiments Taxonomy Isolation
42	Development of strategies for the successful production of yogurt-like products from Tiger nut (Cyperus esculentus L) milk / Entwicklungsstrategien für die erfolgreiche Herstellung von Joghurt-ähnlichen Produkten aus Erdmandelmilch Kizzie-Hayford, Nazir 07 April 2017 (has links) (PDF) Tiger nuts (Cyperus esculentus L) are recognized as a high potential, alternative source of food nutrients. However, there is limited scientific literature on the technological possibilities for developing value-added foods, such as fermented products from tiger nut milk. Therefore, strategies for producing and improving the properties of fermented tiger nut milk were investigated for generating lactose-free, nutritious yogurt-like products with acceptable sensory properties and a prolonged shelf life quality. A wet-milling procedure was standardized for extracting tiger nut milk from tiger nuts, and the effects of the extraction process on nutrient distribution, colour properties and colloidal stability of the milk were analyzed. Next, tiger nut milk was enriched with proteins and/or hydrocolloids and the impact of the additives on the physical properties of the milk were determined. Enriched tiger nut milk was fermented by using classical yogurt cultures and the obtained products were analyzed for the microbiological, physico-chemical and sensory characteristics. Additionally, effects of enriching tiger nut milk with microbial transglutaminase cross-linked proteins on the microbiological and physico-chemical properties were evaluated. Higher wet-milling intensity improved the nutrient composition, colloidal stability and colour of the milk. Enrichment of tiger nut milk with milk proteins and xanthan gum enhanced the viscosity and stability, and after fermentation, led to homogenous gel-like products with superior microbiological, physico-chemical and different sensory properties compared to the fermented plain tiger nut milk. Microbial transglutaminase cross-linked proteins improved the physical characteristics of the fermented product, especially during storage. This product would be relevant in many developing countries with high prevalence of lactose intolerance, limited access to nutritious food but show a high distribution of tiger nut vegetation. / Erdmandeln (Cyperus esculentus L) haben ein hohes Potential als alternative Quelle Lebensmittelinhaltsstoffen. Allerdings gibt es nur in begrenztem Ausmaß Literatur über technologische Möglichkeiten zur Entwicklung von Mehrwert-Lebensmitteln wie fermentierter Erdmandelmilch. Daher wurden Strategien zur Herstellung und Verbesserung der Eigenschaften von fermentierter Erdmandelmilch zur Erzeugung laktosefreier joghurtähnlicher Produkte mit akzeptablen sensorischen Eigenschaften untersucht. Für die Extraktion der Erdmandelmilch wurde ein Nassmahlverfahren standardisiert und der Einfluss des Verfahrens auf die Nährstoffverteilung, die Farbeigenschaften und die kolloidale Stabilität der Milch analysiert. Als nächstes wurde Erdmandelmilch mit Proteinen und/oder Hydrokolloiden angereichert, und der Einfluss der Additive auf die physikalischen Eigenschaften des Extrakts bestimmt. Angereicherte Erdmandelmilch wurde mit klassischen Joghurtkulturen fermentiert, und die mikrobiologischen, physikalisch-chemischen und sensorischen Eigenschaften der Produkte wurden untersucht. Zusätzlich wurden Effekte der Anreicherung von Erdmandelmilch mit enzymatisch vernetzten Proteinen auf die mikrobiologischen und physikalisch-chemischen Eigenschaften bewertet. Eine höhere Nassmahlintensität verbesserte die Nährstoffzusammensetzung, die kolloidale Stabilität und die Farbe der Milch. Die Anreicherung erhöhte die Viskosität und Stabilität und führte nach der Fermentation zu homogenen gelartigen Produkten mit verbesserten mikrobiologischen, physikalisch-chemischen und sensorischen Eigenschaften im Vergleich zur fermentierten Erdmandelmilch. Mikrobielle Transglutaminase-vernetzte Proteine verbesserten die physikalischen Eigenschaften des fermentierten Produkts, insbesondere während der Lagerung. Dieses Produkt wäre in vielen Entwicklungsländern mit hoher Prävalenz von Laktoseintoleranz und begrenztem Zugang zu nahrhaften Lebensmitteln als Alternative von Interesse. Fermentierte Erdmandelmilch Transglutaminase Milchproteine Mikrobiologische physiko-chemische sensorische Eigenschaften Fermented tiger nut milk Transglutaminase milk proteins microbiological physico-chemical sensory properties ddc:620 rvk:VN 8100
43	New insights into the substrate specificities of microbial transglutaminase: a biocatalytic perspective Gundersen, Maria 12 1900 (has links) La transglutaminase microbienne (Microbial transglutaminase : MTG) est fortement exploitée dans l’industrie textile et alimentaire afin de modifier l’apparence et la texture de divers produits. Elle catalyse la formation de liaisons iso-peptidiques entre des protéines par l’entremise d’une réaction de transfert d’acyle entre le groupement γ-carboxamide d’une glutamine provenant d’un substrat donneur d’acyle, et le groupement ε-amino d’une lysine provenant d’un substrat accepteur d’acyle. La MTG est tolérante à un large éventail de conditions réactionnelles, ce qui rend propice le développement de cette enzyme en tant que biocatalyseur. Ayant pour but le développement de la MTG en tant qu’alternative plus soutenable à la synthèse d’amides, nous avons étudié la réactivité d’une gamme de substrats donneurs et accepteurs non-naturels. Des composés chimiquement diversifiés, de faible masse moléculaire, ont été testés en tant que substrats accepteurs alternatifs. Il fut démontré que la MTG accepte une large gamme de composés à cet effet. Nous avons démontré, pour la première fois, que des acides aminés non-ramifiés et courts, tels la glycine, peuvent servir de substrat accepteur. Les α-acides aminés estérifiés Thr, Ser, Cys et Trp, mais pas Ile, sont également réactifs. En étendant la recherche à des composés non-naturels, il fut observé qu’un cycle aromatique est bénéfique pour la réactivité, bien que les substituants réduisent l’activité. Fait notable, des amines de faible masse moléculaire, portant les groupements de forte densité électronique azidure ou alcyne, sont très réactives. La MTG catalyse donc efficacement la modification de peptides qui pourront ensuite être modifiés ou marqués par la chimie ‘click’. Ainsi, la MTG accepte une variété de substrats accepteurs naturels et non-naturels, élargissant la portée de modification des peptides contenant la glutamine. Afin de sonder le potentiel biocatalytique de la MTG par rapport aux substrats donneurs, des analogues plus petits du peptide modèle Z-Gln-Gly furent testés; aucun n’a réagi. Nous avons toutefois démontré, pour la première fois, la faible réactivité d’esters en tant que substrats donneurs de la MTG. L’éventuelle amélioration de cette réactivité permettrait de faire de la MTG un biocatalyseur plus général pour la synthèse d’amides. Mots clés: Lien amide, biocatalyse, biotransformation, transglutaminase, arrimage moléculaire, criblage de substrats, ingénierie de substrats. / Microbial transglutaminase (MTG) is used extensively in the food and textile industry to alter the appearance and texture of products. MTG catalyses the formation of isopeptide linkages between proteins by an acyl transfer reaction between the γ-carboxamide group of a glutamine ‘acyl-donor’ substrate, and the ε-amino group of a lysine ‘acyl-acceptor’ substrate. MTG is tolerant to a broad range of reaction conditions and is therefore suitable for further development as a biocatalyst. Toward developing MTG as a “green” alternative for amide synthesis, we have investigated a range of non-native donor and acceptor substrates to probe the scope of MTG reactivity. Small, chemically varied compounds were tested as alternative acyl-acceptor substrates. We observed a broad acceptor specificity. We show, for the first time, that very short-chain alkyl-based amino acids such as glycine can serve as acceptor substrates. The esterified α-amino acids Thr, Ser, Cys and Trp – but not Ile – also show reactivity. Extending the search to non-natural compounds, an aromatic ring was observed to be beneficial for reactivity, although ring substituents reduced reactivity. Overall, bonding of the amine to a less hindered carbon increases reactivity. Importantly, very small amines carrying either the electron-rich azide or the alkyne groups required for click chemistry were highly reactive as acceptor substrates, providing a ready route to minimally modified, ‘clickable’ peptides. These results demonstrate that MTG is tolerant to a variety of chemically varied natural and non-natural acceptor substrates, which broadens the scope for modification of glutamine-containing peptides. To further probe the biocatalytic potential of MTG in terms of the donor substrate, smaller analogues of the model substrate Z-Gln-Gly were tested. We did not find product formation with substrates smaller than the model substrate. We observed, for the first time, trace esterase activity with MTG. Future improvement of this activity would render MTG a more attractive, general biocatalyst for amide bond formation. Amide bond biocatalysis biotransformations microbial transglutaminase docking substrate screening substrate engineering Lien amide biocatalyse biotransformation transglutaminase arrimage moléculaire criblage de substrats ingénierie de substrats
44	Efeito da adição de amido resistente de milho e enzimas sobre as propriedades da massa de pão e as propriedades físicas do pão de forma. / Effect of the addition of resistant starch and enzymes on the rheological properties of bread dough and physical properties of pan bread. Altuna, Luz 29 September 2015 (has links) O amido resistente de milho (ARM) não é digerido em humanos fornecendo benefícios para a saúde tais como redução do colesterol, do índice glicêmico e fermentação no cólon. Porém, a substituição parcial de farinha de trigo (FT) por ARM em massa de pão resulta na diluição do glúten prejudicando a qualidade do produto. Massa de pão foi produzida com 12,5 g/100g de ARM e os efeitos das enzimas glicose-oxidase (Gox), tranglutaminase (TG) e xilanase (HE) na massa foram estudados. Massa produzida sem ARM e sem enzimas foi considerada padrão e massa produzida com ARM e sem enzimas foi considerada controle para comparação. Uma metodologia foi desenvolvida para medir o torque durante o amassamento em grande escala, utilizando um reômetro dinâmico adaptado. As propriedades reológicas foram avaliadas nos testes de medidas descritivas de textura, adesividade Chen-Hoseney, extensão uniaxial Kieffer, extensão biaxial e testes oscilatórios em reômetro. Pão produzido de acordo com as formulações padrão, controle e ótima foi avaliado com relação ao volume específico (VEP), firmeza do miolo, cor e análise sensorial para o atributo preferência. As três enzimas testadas influenciaram positivamente o torque máximo atingido durante o amassamento que variou entre (8,36 e 9,38) N m. Gox e TG apresentaram efeito positivo na altura máxima desenvolvida pela massa medida em reofermentógrafo enquanto que o efeito da HE foi negativo. Uma formulação com ARM e enzimas apresentou desempenho de panificação similar a massa padrão (altura máxima ajustada igual a (45,5 ± 3,9) mm), correspondente a adição de (4, 2,5 e 0,5) mg/100g de TG, Gox e HE respectivamente (ótima). A formulação ótima apresentou adesividade, trabalho de adesão, coesividade, dureza, resiliência, resistência à extensão e extensibilidade similares a massa padrão e diferentes da massa controle. As enzimas aumentaram o índice de strain hardening reduzido pela adição de ARM. Para o pão de forma, o VEP variou entre (3,16 e 3,64) cm3/g (diferença não significativa) e o pão produzido com a formulação ótima foi o mais escolhido como preferido. Durante o armazenamento por até 7 dias, o ARM diminuiu a taxa de envelhecimento do pão enquanto que as enzimas apresentaram efeito oposto. Em geral, a substituição parcial de FT por ARM reduziu a elasticidade da massa diminuindo a qualidade do pão enquanto que as enzimas minimizaram esse efeito. / Resistant starch (RS) is not digested by humans providing benefits for health such as reduction of blood LDL cholesterol levels, reduction of post-prandial blood glucose and fermentation in the colon. However, partial replacement of wheat flour (WF) with RS prejudices bread quality due to gluten dilution. Dough was formulated with 12.5 g/100g of RS and the effects of the enzymes glucose-oxidase (Gox), tranglutaminase (TG) and xylanase (HE) were studied. Dough produced without RS or enzymes was considered as regular and dough produced with RS and without enzymes was considered as control for comparison. A methodology was developed to measure torque during dough mixing in large scale using a dynamic rheometer. With respect to dough rheology, tests performed included texture profile analysis, Chen-Hoseney stickiness, Kieffer uniaxial extension, biaxial extension and oscillatory tests in rheometer. Bread was produced from regular, control and optimum formulations and the quality was assessed concerning specific volume, firmness, color and preference by sensory panel. The three enzymes tested influenced positively the maximum torque during mixing which varied between (8.36 and 9.38) N m. Gox and TG showed positive effects on the maximum height developed by dough measured in rheofermentometer while HE showed a negative one. A formulation with RS and baking performance similar to regular dough was found (adjusted maximum height equal to (45.5 ± 3.9) mm), corresponding to (4, 2.5 and 0.5) mg/100g of TG, Gox and HE respectively (optimum). The optimum formulation showed stickiness, work of adhesion, cohesiveness, hardness, resilience, resistance to extension and extensibility, similar to the regular dough and statistically different from control dough. Strain hardening index was reduced by the addition of RS and increased by the addition of enzymes. Regarding bread tests, specific volume of bread varied between (3.16 e 3.64) cm3/g (not significant difference) and the bread produced with theoptimum dough was the most preferred by the sensory panel. During 7 days of storage, RS reduced the aging rate while enzymes had the opposite effect. In general, WF replacement by RS reduced dough elasticity affecting the bread quality while enzymes helped minimizing this effect. Amido resistente Baking performance Bread dough Desempenho de panificação Glicose-oxidase Glucose- oxidase Massa de pão Reologia Resistant starch Rheology Torque Torque Transglutaminase Transglutaminase Xilanase Xylanase
45	Synthèse et évaluation pharmacologique d'anticorps couplés avec une nouvelle méthode de conjugaison site spécifique et stoechiométrique via l'enzyme transglutaminase bactérienne / Synthesis and pharmacological evaluation of antibody drug conjugates with a new site specific method and stoechiometric conjugation based on bacterial transglutaminase enzyme Lhospice, Florence 28 November 2018 (has links) La majorité des ADC qui sont actuellement en clinique et en développement sont produits par une conjugaison chimique via les résidus lysine ou cystéine, menant à un produit hétérogène pour leur ratio toxine sur anticorps (DAR). L'objet des travaux de thèse a pour but de décrire la caractérisation in vitro et in vivo de nouveaux ADC optimisés et construits à partir de l'anticorps anti-CD30 cAC10, ayant le même squelette polypetidique que Adcetris, et de comparer les résultats à ce dernier. La transglutaminase bactérienne (BTG) a été utilisée pour conjuguer de manière site-spécifique la MMAE aux glutamines aux positions 295 et 297 du cAC10, amenant à des ADCs homogènes de DAR 4, TG-ADC. Des travaux préliminaires ont permis d’établir les conditions optimales de conjugaison avec un procédé en deux étapes. Les tests de cytotoxicité ont révélé des EC50 comparables entre Adcetris et les TG-ADC. Les données d’efficacité in vivo montrent une efficacité équivalente voire légèrement supérieure pour les TG-ADC que Adcetris. L'étude de biodistribution in vivo dans un modèle avec et sans tumeur est réalisé avec un 125-I TG-ADC et est comparé à 125I-Adcetris. Le TG ADC site spécifique montre une meilleure distribution tumorale. Adcetris a une distribution non médiée par la cible, dans le foie et la rate, plus importante. En ligne avec ces résultats, la dose maximale tolérée des TG ADC est significativement plus élevée que Adcetris chez le rat. Ces résultats suggèrent que les ADC homogènes ont une meilleure pharmacocinétique et un meilleur index thérapeutique comparés aux ADC avec des DAR hétérogènes. / Most ADC that are currently in clinical use or development produced by chemical conjugation of a toxin via either lysine or cysteine residues, inevitably leading to heterogeneous products with variable drug-to-antibody ratios (DARs). Here, we describe the in vitro and in vivo characterization of novel ADCs that are based on the anti-CD30 antibody cAC10, which has the same polypeptide backbone as Adcetris, and compare the results with the latter. Bacterial transglutaminase (BTG) was exploited to site-specifically conjugate derivatives of MMAE to the glutamines at position 295 and 297 of cAC10, yielding homogeneous ADCs with a DAR of 4, TG-ADC. Preliminary works have led to define optimal conditions for conjugation, but also define a two step process. In vitro cell toxicity experiments revealed comparable EC50-values for Adcetris and TG-ADC. The efficacy data have shown slightly better efficacy for TG-ADC compared to Adcetris. Quantitative time-dependent in vivo biodistribution studies in normal and xenografted mice were performed with a selected 125I TG ADC and compared with 125I-Adcetris. Adcetris has an higher liver and spleen unspecific uptakes. In line with these results, the maximum tolerated dose of the BTG-coupled ADC (> 60 mg/kg) was significantly higher than that of ADCETRIS® (18 mg/kg) in rats. These results suggest that homogenous ADCs display improved pharmacokinetics and better therapeutic indexes compared to chemically modified ADCs with variable DARs. Anticorps monoclonal Anticorps conjugués à des toxines Transglutaminase bactérienne Adcetris Conjugaison site-Spécifique Auristatine E Monoclonal antibody Antibodies drug conjugated Bacterial transglutaminase Adcetris Site specific conjugation Auristatine E
46	Nanocomposite immunosensor for anti-transglutaminase antibody Natasha West January 2009 (has links) <p>Coeliac disease (CD) is a gluten intolerance condition that results in the flattening of the villi, which line the bowel. It is the most common cause of malabsorption of food nutrients. This inability to absorb sufficient levels of nutrients causes many of the common symptoms experienced by CD patients. Some of the symptoms, which lead to an increase in mortality rate, include chronic diarrhea, fatigue, iron-deficient anemia and osteoporosis. People with CD have higher than normal levels of certain antibodies in their blood. Thus, the concentration of anti-transglutaminase antibody (anti-tTG) in human sera is an important analytical marker for the diagnosis of CD. An immunosensor is a type of biosensor that has an antigen or antibody fragment as its biological recognition component. The specificity of the molecular recognition of antigens by antibodies to form a stable complex is the basis of immunosensor technology. In this work, overoxidized polypyrrole (OvoxPpy) was electrosynthesized as a noval sensor platform on a glassy carbon electrode (GCE). The OvoxPpy was then doped with gold-nanoparticles (GNP) by electrodeposition using cyclic voltammetry to form GNP\|OvoxPpy\|\|GCE electrode system. Morphology and size of the GNP\|OvoxPpy\|\|GCE nanocomposite were determined using scanning electron microscopy. The electrochemical immunosensor for anti-tTG antibodies was prepared by immobilizing transglutaminase antigen (tTG-antigen) onto the GNP\|OvoxPpy\|\|GCE by drop coating and allowed to incubate for 2 hrs. The electrochemical characterization of the nanocomposite platform and immunosensor were studied by voltammetry and electrochemical impedance spectroscopy (EIS)...</p> Biosensor Immunosensor Polypyrrole Gold nanoparticles Cyclic voltammetry Square wave voltammetry Electrochemical impedance spectroscopy Coeliac disease Transglutaminase (tTG) antigen Anti-transglutaminase antibodies.
47	New insights into the substrate specificities of microbial transglutaminase: a biocatalytic perspective Gundersen, Maria 12 1900 (has links) La transglutaminase microbienne (Microbial transglutaminase : MTG) est fortement exploitée dans l’industrie textile et alimentaire afin de modifier l’apparence et la texture de divers produits. Elle catalyse la formation de liaisons iso-peptidiques entre des protéines par l’entremise d’une réaction de transfert d’acyle entre le groupement γ-carboxamide d’une glutamine provenant d’un substrat donneur d’acyle, et le groupement ε-amino d’une lysine provenant d’un substrat accepteur d’acyle. La MTG est tolérante à un large éventail de conditions réactionnelles, ce qui rend propice le développement de cette enzyme en tant que biocatalyseur. Ayant pour but le développement de la MTG en tant qu’alternative plus soutenable à la synthèse d’amides, nous avons étudié la réactivité d’une gamme de substrats donneurs et accepteurs non-naturels. Des composés chimiquement diversifiés, de faible masse moléculaire, ont été testés en tant que substrats accepteurs alternatifs. Il fut démontré que la MTG accepte une large gamme de composés à cet effet. Nous avons démontré, pour la première fois, que des acides aminés non-ramifiés et courts, tels la glycine, peuvent servir de substrat accepteur. Les α-acides aminés estérifiés Thr, Ser, Cys et Trp, mais pas Ile, sont également réactifs. En étendant la recherche à des composés non-naturels, il fut observé qu’un cycle aromatique est bénéfique pour la réactivité, bien que les substituants réduisent l’activité. Fait notable, des amines de faible masse moléculaire, portant les groupements de forte densité électronique azidure ou alcyne, sont très réactives. La MTG catalyse donc efficacement la modification de peptides qui pourront ensuite être modifiés ou marqués par la chimie ‘click’. Ainsi, la MTG accepte une variété de substrats accepteurs naturels et non-naturels, élargissant la portée de modification des peptides contenant la glutamine. Afin de sonder le potentiel biocatalytique de la MTG par rapport aux substrats donneurs, des analogues plus petits du peptide modèle Z-Gln-Gly furent testés; aucun n’a réagi. Nous avons toutefois démontré, pour la première fois, la faible réactivité d’esters en tant que substrats donneurs de la MTG. L’éventuelle amélioration de cette réactivité permettrait de faire de la MTG un biocatalyseur plus général pour la synthèse d’amides. Mots clés: Lien amide, biocatalyse, biotransformation, transglutaminase, arrimage moléculaire, criblage de substrats, ingénierie de substrats. / Microbial transglutaminase (MTG) is used extensively in the food and textile industry to alter the appearance and texture of products. MTG catalyses the formation of isopeptide linkages between proteins by an acyl transfer reaction between the γ-carboxamide group of a glutamine ‘acyl-donor’ substrate, and the ε-amino group of a lysine ‘acyl-acceptor’ substrate. MTG is tolerant to a broad range of reaction conditions and is therefore suitable for further development as a biocatalyst. Toward developing MTG as a “green” alternative for amide synthesis, we have investigated a range of non-native donor and acceptor substrates to probe the scope of MTG reactivity. Small, chemically varied compounds were tested as alternative acyl-acceptor substrates. We observed a broad acceptor specificity. We show, for the first time, that very short-chain alkyl-based amino acids such as glycine can serve as acceptor substrates. The esterified α-amino acids Thr, Ser, Cys and Trp – but not Ile – also show reactivity. Extending the search to non-natural compounds, an aromatic ring was observed to be beneficial for reactivity, although ring substituents reduced reactivity. Overall, bonding of the amine to a less hindered carbon increases reactivity. Importantly, very small amines carrying either the electron-rich azide or the alkyne groups required for click chemistry were highly reactive as acceptor substrates, providing a ready route to minimally modified, ‘clickable’ peptides. These results demonstrate that MTG is tolerant to a variety of chemically varied natural and non-natural acceptor substrates, which broadens the scope for modification of glutamine-containing peptides. To further probe the biocatalytic potential of MTG in terms of the donor substrate, smaller analogues of the model substrate Z-Gln-Gly were tested. We did not find product formation with substrates smaller than the model substrate. We observed, for the first time, trace esterase activity with MTG. Future improvement of this activity would render MTG a more attractive, general biocatalyst for amide bond formation. Amide bond biocatalysis biotransformations microbial transglutaminase docking substrate screening substrate engineering Lien amide biocatalyse biotransformation transglutaminase arrimage moléculaire criblage de substrats ingénierie de substrats
48	Nanocomposite immunosensor for anti-transglutaminase antibody Natasha West January 2009 (has links) <p>Coeliac disease (CD) is a gluten intolerance condition that results in the flattening of the villi, which line the bowel. It is the most common cause of malabsorption of food nutrients. This inability to absorb sufficient levels of nutrients causes many of the common symptoms experienced by CD patients. Some of the symptoms, which lead to an increase in mortality rate, include chronic diarrhea, fatigue, iron-deficient anemia and osteoporosis. People with CD have higher than normal levels of certain antibodies in their blood. Thus, the concentration of anti-transglutaminase antibody (anti-tTG) in human sera is an important analytical marker for the diagnosis of CD. An immunosensor is a type of biosensor that has an antigen or antibody fragment as its biological recognition component. The specificity of the molecular recognition of antigens by antibodies to form a stable complex is the basis of immunosensor technology. In this work, overoxidized polypyrrole (OvoxPpy) was electrosynthesized as a noval sensor platform on a glassy carbon electrode (GCE). The OvoxPpy was then doped with gold-nanoparticles (GNP) by electrodeposition using cyclic voltammetry to form GNP\|OvoxPpy\|\|GCE electrode system. Morphology and size of the GNP\|OvoxPpy\|\|GCE nanocomposite were determined using scanning electron microscopy. The electrochemical immunosensor for anti-tTG antibodies was prepared by immobilizing transglutaminase antigen (tTG-antigen) onto the GNP\|OvoxPpy\|\|GCE by drop coating and allowed to incubate for 2 hrs. The electrochemical characterization of the nanocomposite platform and immunosensor were studied by voltammetry and electrochemical impedance spectroscopy (EIS)...</p> Biosensor Immunosensor Polypyrrole Gold nanoparticles Cyclic voltammetry Square wave voltammetry Electrochemical impedance spectroscopy Coeliac disease Transglutaminase (tTG) antigen Anti-transglutaminase antibodies.
49	Nanocomposite immunosensor for anti-transglutaminase antibody West, Natasha January 2009 (has links) Magister Scientiae - MSc / Coeliac disease (CD) is a gluten intolerance condition that results in the flattening of the villi, which line the bowel. It is the most common cause of malabsorption of food nutrients. This inability to absorb sufficient levels of nutrients causes many of the common symptoms experienced by CD patients. Some of the symptoms, which lead to an increase in mortality rate, include chronic diarrhea, fatigue, iron-deficient anemia and osteoporosis. People with CD have higher than normal levels of certain antibodies in their blood. Thus, the concentration of anti-transglutaminase antibody (anti-tTG) in human sera is an important analytical marker for the diagnosis of CD. An immunosensor is a type of biosensor that has an antigen or antibody fragment as its biological recognition component. The specificity of the molecular recognition of antigens by antibodies to form a stable complex is the basis of immunosensor technology. In this work, overoxidized polypyrrole (OvoxPpy) was electrosynthesized as a noval sensor platform on a glassy carbon electrode (GCE). The OvoxPpy was then doped with gold-nanoparticles (GNP) by electrodeposition using cyclic voltammetry to form GNP\|OvoxPpy\|\|GCE electrode system. Morphology and size of the GNP\|OvoxPpy\|\|GCE nanocomposite were determined using scanning electron microscopy. The electrochemical immunosensor for anti-tTG antibodies was prepared by immobilizing transglutaminase antigen (tTG-antigen) onto the GNP\|OvoxPpy\|\|GCE by drop coating and allowed to incubate for 2 hrs. The electrochemical characterization of the nanocomposite platform and immunosensor were studied by voltammetry and electrochemical impedance spectroscopy (EIS). Charge transfer resistance, Rct (obtained from EIS data fitting) of [Fe (CN)6]3-/4- redox probe was used as the analytical parameter for measuring the interfacial kinetics which occurred as a result of the bio-recognition event (affinitive binding) between the tTG-antigen and anti-tTG antibody. Rct was found to increase with increased concentration of the antibody as a result of the reluctance to the flow of redox probe charge across the interface. Antibody concentration as low as in 1:4000 dilutions was detected. / South Africa Biosensor Immunosensor Polypyrrole Gold nanoparticles Cyclic voltammetry Square wave voltammetry Electrochemical impedance spectroscopy Coeliac disease Transglutaminase (tTG) antigen Anti-transglutaminase antibodies
50	Efeito da adição de amido resistente de milho e enzimas sobre as propriedades da massa de pão e as propriedades físicas do pão de forma. / Effect of the addition of resistant starch and enzymes on the rheological properties of bread dough and physical properties of pan bread. Luz Altuna 29 September 2015 (has links) O amido resistente de milho (ARM) não é digerido em humanos fornecendo benefícios para a saúde tais como redução do colesterol, do índice glicêmico e fermentação no cólon. Porém, a substituição parcial de farinha de trigo (FT) por ARM em massa de pão resulta na diluição do glúten prejudicando a qualidade do produto. Massa de pão foi produzida com 12,5 g/100g de ARM e os efeitos das enzimas glicose-oxidase (Gox), tranglutaminase (TG) e xilanase (HE) na massa foram estudados. Massa produzida sem ARM e sem enzimas foi considerada padrão e massa produzida com ARM e sem enzimas foi considerada controle para comparação. Uma metodologia foi desenvolvida para medir o torque durante o amassamento em grande escala, utilizando um reômetro dinâmico adaptado. As propriedades reológicas foram avaliadas nos testes de medidas descritivas de textura, adesividade Chen-Hoseney, extensão uniaxial Kieffer, extensão biaxial e testes oscilatórios em reômetro. Pão produzido de acordo com as formulações padrão, controle e ótima foi avaliado com relação ao volume específico (VEP), firmeza do miolo, cor e análise sensorial para o atributo preferência. As três enzimas testadas influenciaram positivamente o torque máximo atingido durante o amassamento que variou entre (8,36 e 9,38) N m. Gox e TG apresentaram efeito positivo na altura máxima desenvolvida pela massa medida em reofermentógrafo enquanto que o efeito da HE foi negativo. Uma formulação com ARM e enzimas apresentou desempenho de panificação similar a massa padrão (altura máxima ajustada igual a (45,5 ± 3,9) mm), correspondente a adição de (4, 2,5 e 0,5) mg/100g de TG, Gox e HE respectivamente (ótima). A formulação ótima apresentou adesividade, trabalho de adesão, coesividade, dureza, resiliência, resistência à extensão e extensibilidade similares a massa padrão e diferentes da massa controle. As enzimas aumentaram o índice de strain hardening reduzido pela adição de ARM. Para o pão de forma, o VEP variou entre (3,16 e 3,64) cm3/g (diferença não significativa) e o pão produzido com a formulação ótima foi o mais escolhido como preferido. Durante o armazenamento por até 7 dias, o ARM diminuiu a taxa de envelhecimento do pão enquanto que as enzimas apresentaram efeito oposto. Em geral, a substituição parcial de FT por ARM reduziu a elasticidade da massa diminuindo a qualidade do pão enquanto que as enzimas minimizaram esse efeito. / Resistant starch (RS) is not digested by humans providing benefits for health such as reduction of blood LDL cholesterol levels, reduction of post-prandial blood glucose and fermentation in the colon. However, partial replacement of wheat flour (WF) with RS prejudices bread quality due to gluten dilution. Dough was formulated with 12.5 g/100g of RS and the effects of the enzymes glucose-oxidase (Gox), tranglutaminase (TG) and xylanase (HE) were studied. Dough produced without RS or enzymes was considered as regular and dough produced with RS and without enzymes was considered as control for comparison. A methodology was developed to measure torque during dough mixing in large scale using a dynamic rheometer. With respect to dough rheology, tests performed included texture profile analysis, Chen-Hoseney stickiness, Kieffer uniaxial extension, biaxial extension and oscillatory tests in rheometer. Bread was produced from regular, control and optimum formulations and the quality was assessed concerning specific volume, firmness, color and preference by sensory panel. The three enzymes tested influenced positively the maximum torque during mixing which varied between (8.36 and 9.38) N m. Gox and TG showed positive effects on the maximum height developed by dough measured in rheofermentometer while HE showed a negative one. A formulation with RS and baking performance similar to regular dough was found (adjusted maximum height equal to (45.5 ± 3.9) mm), corresponding to (4, 2.5 and 0.5) mg/100g of TG, Gox and HE respectively (optimum). The optimum formulation showed stickiness, work of adhesion, cohesiveness, hardness, resilience, resistance to extension and extensibility, similar to the regular dough and statistically different from control dough. Strain hardening index was reduced by the addition of RS and increased by the addition of enzymes. Regarding bread tests, specific volume of bread varied between (3.16 e 3.64) cm3/g (not significant difference) and the bread produced with theoptimum dough was the most preferred by the sensory panel. During 7 days of storage, RS reduced the aging rate while enzymes had the opposite effect. In general, WF replacement by RS reduced dough elasticity affecting the bread quality while enzymes helped minimizing this effect. Amido resistente Desempenho de panificação Glicose-oxidase Massa de pão Reologia Torque Transglutaminase Xilanase Baking performance Bread dough Glucose- oxidase Resistant starch Rheology Torque Transglutaminase Xylanase

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