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11	Estudo proteômico para determinação da expressão relativa das isoformas de VDAC e caracterização dos sítios de ligação da hexoquinase em mitocôndrias cerebrais de rato, boi e ave / Proteomic study to determination of relative expression of VDAC isoforms and characterization of hexokinase binding sites in rat, bovine and avian brain mitochondria Poleti, Mirele Daiana 12 December 2008 (has links) Os canais seletivos a ânions dependente de voltagem (VDACs) são um grupo de proteínas, primeiramente identificadas na membrana mitocondrial externa, capazes de formar estruturas de poros hidrofílicos em membranas. As VDACs são conhecidas pela sua função essencial no metabolismo celular e nos estágios recentes de apoptose. Em mamíferos, foram identificadas três isoformas de VDACs (VDAC1, 2 e 3). Uma pesquisa proteômica, consistindo de eletroforese bi-dimensional seguida por western blotting com anticorpos anti-VDAC 1, anti-VDAC 2 e anti-VDAC 3 e espectrometria de massas com fonte de ionização/desorção à laser assistido por matriz e tempo de vôo foi utilizada para estudar a expressão das isoformas de VDAC em mitocôndrias cerebrais de aves, ratos e bois. Foi estudada a possibilidade que diferenças na expressão relativa das isoformas de VDAC possam ser um fator determinante da proporção espécie-dependente dos sítios de ligação da hexoquinase tipo A: tipo B nas mitocôndrias cerebrais. Os spots foram caracterizados, e a intensidade de sinal foi comparada entre os spots. VDAC1 e VDAC2 foram divididas dentro de múltiplos spots. A VDAC1 foi dividida em dois spots nos géis bi-dimensionais realizados com amostras de cérebros de ratos e bois, e três spots para cérebros de aves. A VDAC2 foi separada em três, cinco e dois spots para cérebros de ratos, bois e aves, respectivamente. Os resultados reportam uma heterogeneidade de carga das VDACs 1 e 2 nos cérebros analisados. A VDAC1 foi a mais expressa das três isoformas. Além disso, a expressão da VDAC1 mais VDAC2 foi muito maior em cérebros de aves e bois do que em cérebros de ratos. Mitocôndrias de cérebro de aves mostraram uma maior expressão de VDAC1 e menor de VDAC2. As mitocôndrias de cérebro bovino apresentaram os níveis mais altos de VDAC2. A VDAC3 não foi detectada nos cérebros das espécies estudadas. / The voltage dependent anion selective channels (VDACs) are a group of proteins first identified in the mitochondrial outer membrane that are able to form hydrophilic pore structures in membranes. VDAC are known to play an essential role in cellular metabolism and in the early stages of apoptosis. In mammals, three VDACs isoforms (VDAC1, 2, 3) have been identified. A proteomic approach, consisting of two dimensional electrophoresis, followed by western blotting with anti-VDAC 1, anti-VDAC 2 and anti-VDAC 3 and by matrix assisted laser desorption/ionization time of flight mass spectrometry was used to study the expression of VDAC isoforms in rat, bovine and avian brain mitochondria. We were studying the possibility that differences in the relative expression of VDAC isoforms may be a factor in determining the species-dependent ratio of type A: type B hexokinase binding sites on brain mitochondria. The spots were characterized, and the signal intensities among spots were compared. VDAC1 and VDAC2 were divided into multiple spots. VDAC1 was divided in two spots in two dimensional gels of rat and bovine brains and three spots in avian brains. VDAC2 was separated into three, five and two spots in rat, bovine and avian brains, respectively. The results report charge heterogeneity of VDACs 1 and 2 in the analyzed brains. VDAC1 was the most abundantly expressed of the three isoforms. Moreover the expression of VDAC1 plus VDAC2 was much higher in avian and bovine brains than in rat brains. Avian brain mitochondria showed the highest expression of VDAC1 and the lowest of VDAC2. Bovine brain mitochondria had the highest levels of VDAC2. No VDAC 3 was detected in studied species brains. Apoptose Apoptosis Glicólise Glycolysis Hexokinase Hexoquinase Isoformas Isoforms VDAC VDAC
12	Lokalizace cytosolických izoforem kreatin kinázy a hexokinázy v hypetrofovaném srdci / Localization of cytosolic isoforms of creatine kinase and hexokinase in hypertrophied heart Heleš, Mário January 2017 (has links) Hypertrophy of the heart is tightly bound to the metabolic adaptations and a cellular remodeling. An important and dynamic system contributing to the maintenance of energy homeostasis is the creatine kinase system (CK). The microcompartmentalization of CK isoforms maintains the flux of ATP between energy production and consumption sites and ensures the effectiveness of the CK system. Changes in expression and activity of CK isoforms during hypertrophy are already well described - to extend this knowledge, this thesis quantified changes in association of cytosolic CK isoforms and sarcomeres. Another essential system, maintaining homeostasis in overloaded heart is composed of the hexokinase (HK) isoforms, located also in cytosol and in mitochondrial compartment. HK1 is associated with mitochondria under physiological conditions, maintaining mitochondrial membrane potential, while HK2 is located mainly in the cytosol. Under stress conditions translocation of HK2 into mitochondrial membrane occurs, which increases the direct supply of ADP to complex V of the respiratory chain and decreases the probability of apoptosis activation. We analyzed association of individual HK isoforms with mitochondria within the second aim of this thesis. Third aim of the thesis was to characterize changes in the CK and M...
13	Regulation of glucose-6-phosphate dehydrogenase and hexokinase in anoxia-tolerant marine molluscs: role of reversible protein phosphorylation / Lama, Judeh, January 1900 (has links) Thesis (M.Sc.) - Carleton University, 2008. / Includes bibliographical references (p. 95-106). Also available in electronic format on the Internet.
14	Estudo proteômico para determinação da expressão relativa das isoformas de VDAC e caracterização dos sítios de ligação da hexoquinase em mitocôndrias cerebrais de rato, boi e ave / Proteomic study to determination of relative expression of VDAC isoforms and characterization of hexokinase binding sites in rat, bovine and avian brain mitochondria Mirele Daiana Poleti 12 December 2008 (has links) Os canais seletivos a ânions dependente de voltagem (VDACs) são um grupo de proteínas, primeiramente identificadas na membrana mitocondrial externa, capazes de formar estruturas de poros hidrofílicos em membranas. As VDACs são conhecidas pela sua função essencial no metabolismo celular e nos estágios recentes de apoptose. Em mamíferos, foram identificadas três isoformas de VDACs (VDAC1, 2 e 3). Uma pesquisa proteômica, consistindo de eletroforese bi-dimensional seguida por western blotting com anticorpos anti-VDAC 1, anti-VDAC 2 e anti-VDAC 3 e espectrometria de massas com fonte de ionização/desorção à laser assistido por matriz e tempo de vôo foi utilizada para estudar a expressão das isoformas de VDAC em mitocôndrias cerebrais de aves, ratos e bois. Foi estudada a possibilidade que diferenças na expressão relativa das isoformas de VDAC possam ser um fator determinante da proporção espécie-dependente dos sítios de ligação da hexoquinase tipo A: tipo B nas mitocôndrias cerebrais. Os spots foram caracterizados, e a intensidade de sinal foi comparada entre os spots. VDAC1 e VDAC2 foram divididas dentro de múltiplos spots. A VDAC1 foi dividida em dois spots nos géis bi-dimensionais realizados com amostras de cérebros de ratos e bois, e três spots para cérebros de aves. A VDAC2 foi separada em três, cinco e dois spots para cérebros de ratos, bois e aves, respectivamente. Os resultados reportam uma heterogeneidade de carga das VDACs 1 e 2 nos cérebros analisados. A VDAC1 foi a mais expressa das três isoformas. Além disso, a expressão da VDAC1 mais VDAC2 foi muito maior em cérebros de aves e bois do que em cérebros de ratos. Mitocôndrias de cérebro de aves mostraram uma maior expressão de VDAC1 e menor de VDAC2. As mitocôndrias de cérebro bovino apresentaram os níveis mais altos de VDAC2. A VDAC3 não foi detectada nos cérebros das espécies estudadas. / The voltage dependent anion selective channels (VDACs) are a group of proteins first identified in the mitochondrial outer membrane that are able to form hydrophilic pore structures in membranes. VDAC are known to play an essential role in cellular metabolism and in the early stages of apoptosis. In mammals, three VDACs isoforms (VDAC1, 2, 3) have been identified. A proteomic approach, consisting of two dimensional electrophoresis, followed by western blotting with anti-VDAC 1, anti-VDAC 2 and anti-VDAC 3 and by matrix assisted laser desorption/ionization time of flight mass spectrometry was used to study the expression of VDAC isoforms in rat, bovine and avian brain mitochondria. We were studying the possibility that differences in the relative expression of VDAC isoforms may be a factor in determining the species-dependent ratio of type A: type B hexokinase binding sites on brain mitochondria. The spots were characterized, and the signal intensities among spots were compared. VDAC1 and VDAC2 were divided into multiple spots. VDAC1 was divided in two spots in two dimensional gels of rat and bovine brains and three spots in avian brains. VDAC2 was separated into three, five and two spots in rat, bovine and avian brains, respectively. The results report charge heterogeneity of VDACs 1 and 2 in the analyzed brains. VDAC1 was the most abundantly expressed of the three isoforms. Moreover the expression of VDAC1 plus VDAC2 was much higher in avian and bovine brains than in rat brains. Avian brain mitochondria showed the highest expression of VDAC1 and the lowest of VDAC2. Bovine brain mitochondria had the highest levels of VDAC2. No VDAC 3 was detected in studied species brains. Apoptose Glicólise Hexoquinase Isoformas VDAC Apoptosis Glycolysis Hexokinase Isoforms VDAC
15	Effects of Endurance Training on the AMPK Response to Exercise. Chesser, David Gerald 07 December 2007 (has links) (PDF) Activation of AMP-activated protein kinase (AMPK) results in the upregulation of several intracellular systems which help to prepare a cell for a high energy challenge. The magnitude of the AMPK response to a 10 min bout of exercise has been found to decrease in red quadriceps (RQ) following training, while putative AMPK roles seem to be maintained; specifically, the biogenesis of mitochondria and higher levels of hexokinase II and glucose transporter 4 (GLUT4). If the AMPK response to exercise is responsible in part for these adaptations, how can they be maintained if the AMPK response is attenuated? The purpose of this study was to determine whether phosphorylation of AMPK in RQ increases during 2-hr training bouts after rats have trained for 8 wks. Male Sprague-Dawley rats ran up to 30 m/min up a 15% grade, 2 hr/day for 8 wks. On the final bout of exercise, trained rats ran for 0 (TRC), 30 (TR1), or 120 min (TR2) up a 15% grade at 30 m/min. Red quadriceps (RQ), soleus, and white quadriceps (WQ) were immediately collected and frozen for analysis. Citrate synthase activity increased in RQ (79 ± 3 vs. 37 ± 4 µmol/g/min) and soleus (64 ± 4 vs. 35 ± 2 µmol/g/min) but not in WQ compared to non-trained controls. In trained rats, maximal increases in T-172 phosphorylation of AMPK occurred after 30 min of exercise (relative values = 1.29 ± 0.06 vs. 1.00 ± 0.06). AMPK phosphorylation did not change significantly in trained rats that ran for 2 hrs (1.31 ± 0.09) compared to rats that ran for 30 min. Similarly, maximal increases in AMPK activity in trained rats occurred after 30 min of exercise (pmoles/min/mg = 2.67 ± .05 vs. 1.09 ± .41) and AMPK activity did not change significantly in trained rats that ran for 2 hrs (2.79 ± .17) compared to rats that ran for 30 min. Previous studies demonstrated a 2−3 fold increase in AMPK activity in non-trained rats after 30 min of exercise at lower work rates. These results demonstrate that the AMPK response to exercise is attenuated even after two-hr bouts of exercise. This implies that the increase in mitochondrial oxidative enzymes, GLUT4, and hexokinase II may be maintained by signals other than the AMPK signaling system. The CREB signaling pathway is one such system. Western analysis of phospho-CREB (Ser133) showed a statistically significant increase in phospho-CREB content in trained rats relative to control. No change in phospho-CREB protein expression was observed between TRC, TR1, and TR2 rats. Significant increases of muscle phospho-CREB content in TRC relative to untrained rats suggest that CREB remains phosphorylated in trained rats even after 24 hrs of rest. Accordingly, chronically increased phospho-CREB in muscle of trained rats relative to controls may explain in part how increased levels of mitochondria are maintained in the face of reduced AMPK response. Alternatively, the attenuated AMPK response may still be above the threshold required for inducing adaptations to endurance training. AMPK GLUT4 hexokinase II mitochondria CREB Cell and Developmental Biology Physiology
16	REDD1 contribue au dialogue entre le métabolisme énergétique et la masse musculaire / REDD1 contributes to the crosstalk between energetic metabolism and skeletal muscle mass Britto, Florian 23 October 2015 (has links) REDD1 contribue au dialogue entre le métabolisme énergétique et la masse musculaire.REDD1 est une protéine ubiquitaire et conservée qui est exprimée en réponse à de nombreux stress et pathologies associés à une atrophie du muscle squelettique, un paramètre corrélé à la mortalité des patients. REDD1 est connue pour inhiber la voie Akt/mTORC1 qui contrôle la synthèse des protéines (composants majoritaires du muscle), mais également d'autres macromolécules tels les ribosomes, les nucléotides ou le glycogène. Nos travaux montrent, grâce à un modèle murin, que REDD1 est capable d'une part d'inhiber la synthèse protéique ce qui conduit à l'atrophie du muscle, et d'autre part de réduire le stockage du glycogène musculaire. Cependant, sa délétion est responsable d'une augmentation du métabolisme basal, d'une réduction de la capacité d'exercice et d'une aggravation de l'atrophie musculaire en situation d'hypoxie. Ces altérations du métabolisme ne sont pas liées à un dysfonctionnement mitochondrial, mais associées à une moindre inhibition de la signalisation d'Akt et/ou mTORC1, tous deux responsables de l'activation de processus anaboliques couteux en énergie. Pris ensembles, ces résultats suggèrent que REDD1 agit comme modérateur de la dépense en ATP dans des situations de stress énergétique. / REDD1 contributes to the crosstalk between energetic metabolism and skeletal muscle mass. REDD1 is a ubiquitous and conserved protein, which is expressed in response to numerous stresses and pathologies responsible of muscle atrophy, a parameter correlated with patient mortality. REDD1 is known to inhibit Akt/mTORC1 pathway which controls synthesis of proteins (the major component of muscle) and other macromolecules such as ribosome, nucleotide or glycogen. Our work shows on a mice model that REDD1 inhibits protein synthesis, leading to skeletal muscle atrophy, and reduces muscle glycogen storage. However, REDD1 deletion is responsible of an increase in basal metabolism, a reduction of exercise capacity and an exacerbation of hypoxia-induced skeletal muscle atrophy. These metabolic alterations are not associated with a mitochondrial dysfunction but rather with an hyper activation of the Akt/mTORC1 pathway which is responsible for the stimulation of energy demanding processes. Altogether, these results strongly suggest that REDD1 acts for moderating ATP demand in energetic stress conditions Akt/mTORC1 Glycogène Muscle squelettique Hexokinase II Mitochondrie Balance protéique Akt/mTORC1 Glycogen Skeletal muscle Hexokinase II Mitochondria Protein balance
17	Extraction, purification et caractérisation d’isoformes d’hexokinase du tubercule de pomme de terre (Solanum tuberosum) Moisan, Marie-Claude 12 1900 (has links) L’hexokinase (HK) est la première enzyme du métabolisme des hexoses et catalyse la réaction qui permet aux hexoses d’entrer dans le pool des hexoses phosphates et donc par le fait même la glycolyse. Bien que le glucose soit son principal substrat, cette enzyme peut aussi phosphoryler le mannose et le fructose. Malgré son importance dans le métabolisme primaire, l’HK n’a jamais été purifiée à homogénéité sous forme native. Le but de ce travail était donc de purifier une isoforme d’HK à partir de tubercule de Solanum tuberosum et par la suite de caractériser ses propriétés cinétiques. Bien avant que je commence mon travail, un groupe de recherche avait déjà séparé et partiellement purifié trois isoformes d’HK de S. tuberosum. Un protocole d’extraction était donc disponible, mais l’HK ainsi extraite était peu stable d’où le besoin d’y apporter certaines modifications. En y ajoutant certains inhibiteurs de protéases ainsi qu’en modifiant les concentrations de certains éléments, le tampon d’extraction ainsi modifié a permis d’obtenir un extrait dont l’activité HK était stable pendant au moins 72h après l’extraction, en empêchant la dégradation. À l’aide du tampon d’extraction optimisé et d’une chromatographie sur colonne de butyl sépharose, il a été possible de séparer 4 isoformes d’HKs. Par la suite, une isoforme d’HK (HK1) a été purifiée à l’homogénéité à l’aide de 5 étapes de chromatographie supplémentaires. En plus de caractériser les propriétés cinétiques de cette enzyme, l’analyse de séquençage par MS/MS a permis de l’associer au produit du gène StHK1 de Solanum tuberosum. Avec une activité spécifique de 10.2 U/mg de protéine, il s’agit de l’HK purifiée avec l’activité spécifique la plus élevée jamais rapportée d’un tissu végétal.L’ensemble des informations recueillies lors de la purification de HK1 a ensuite été utilisée pour commencer la purification d’une deuxième isoforme (HK3). Ce travail a permis de donner des lignes directrices pour la purification de cette isoforme et certains résultats préliminaires sur sa caractérisation enzymatique. / Hexokinase (HK) catalyzes the first step of hexose metabolism by phosphorylating hexose to generate the corresponding hexose phosphate thereby allowing hexose entrance in glycolysis. Even though glucose is the main substrate, HK can also phosphorylate a broad spectrum of hexoses. Despite its importance this enzyme has never been purified to homogeneity in a native form. The aim of this work was therefore to purify this enzyme from Solanum tuberosum tubers and subsequently characterize its kinetic properties. Before I started this work, another group had already separated and partially purified 3 HK isoform from S. tuberosum. An extraction protocol was available but improvement was necessary since the extracted HK had little stability. By adding some protease inhibitors and by modifying the concentration of certain components in the extraction buffer we were able to obtain an extract with a HK activity stable for at least 72 h after extraction by preventing degradation. With this buffer and chromatography on butyl sepharose it was possible to separate 4 HK isoforms from S. tuberosum. After 5 more chromatographic steps, one HK isoform was purified to homogeneity (HK1). This enzyme was characterized and sequenced by MS/MS. We were able to associate this protein sequence with the gene product of StHK1 from S. tuberosum. With a specific activity of 10.2 U/mg of protein, this is the HK with the highest specific activity ever reported from a plant tissue. All the information gathered while purifying HK1 was used to undertake the purification of a second isoform (HK3). We were able to obtain preliminary results on its kinetic properties. Hexokinase Tubercule de pomme de terre Purification de protéine Caractérisation enzymatique Hexokinase Potato tuber Protein purification Protein characterization
18	Extraction, purification et caractérisation d’isoformes d’hexokinase du tubercule de pomme de terre (Solanum tuberosum) Moisan, Marie-Claude 12 1900 (has links) L’hexokinase (HK) est la première enzyme du métabolisme des hexoses et catalyse la réaction qui permet aux hexoses d’entrer dans le pool des hexoses phosphates et donc par le fait même la glycolyse. Bien que le glucose soit son principal substrat, cette enzyme peut aussi phosphoryler le mannose et le fructose. Malgré son importance dans le métabolisme primaire, l’HK n’a jamais été purifiée à homogénéité sous forme native. Le but de ce travail était donc de purifier une isoforme d’HK à partir de tubercule de Solanum tuberosum et par la suite de caractériser ses propriétés cinétiques. Bien avant que je commence mon travail, un groupe de recherche avait déjà séparé et partiellement purifié trois isoformes d’HK de S. tuberosum. Un protocole d’extraction était donc disponible, mais l’HK ainsi extraite était peu stable d’où le besoin d’y apporter certaines modifications. En y ajoutant certains inhibiteurs de protéases ainsi qu’en modifiant les concentrations de certains éléments, le tampon d’extraction ainsi modifié a permis d’obtenir un extrait dont l’activité HK était stable pendant au moins 72h après l’extraction, en empêchant la dégradation. À l’aide du tampon d’extraction optimisé et d’une chromatographie sur colonne de butyl sépharose, il a été possible de séparer 4 isoformes d’HKs. Par la suite, une isoforme d’HK (HK1) a été purifiée à l’homogénéité à l’aide de 5 étapes de chromatographie supplémentaires. En plus de caractériser les propriétés cinétiques de cette enzyme, l’analyse de séquençage par MS/MS a permis de l’associer au produit du gène StHK1 de Solanum tuberosum. Avec une activité spécifique de 10.2 U/mg de protéine, il s’agit de l’HK purifiée avec l’activité spécifique la plus élevée jamais rapportée d’un tissu végétal.L’ensemble des informations recueillies lors de la purification de HK1 a ensuite été utilisée pour commencer la purification d’une deuxième isoforme (HK3). Ce travail a permis de donner des lignes directrices pour la purification de cette isoforme et certains résultats préliminaires sur sa caractérisation enzymatique. / Hexokinase (HK) catalyzes the first step of hexose metabolism by phosphorylating hexose to generate the corresponding hexose phosphate thereby allowing hexose entrance in glycolysis. Even though glucose is the main substrate, HK can also phosphorylate a broad spectrum of hexoses. Despite its importance this enzyme has never been purified to homogeneity in a native form. The aim of this work was therefore to purify this enzyme from Solanum tuberosum tubers and subsequently characterize its kinetic properties. Before I started this work, another group had already separated and partially purified 3 HK isoform from S. tuberosum. An extraction protocol was available but improvement was necessary since the extracted HK had little stability. By adding some protease inhibitors and by modifying the concentration of certain components in the extraction buffer we were able to obtain an extract with a HK activity stable for at least 72 h after extraction by preventing degradation. With this buffer and chromatography on butyl sepharose it was possible to separate 4 HK isoforms from S. tuberosum. After 5 more chromatographic steps, one HK isoform was purified to homogeneity (HK1). This enzyme was characterized and sequenced by MS/MS. We were able to associate this protein sequence with the gene product of StHK1 from S. tuberosum. With a specific activity of 10.2 U/mg of protein, this is the HK with the highest specific activity ever reported from a plant tissue. All the information gathered while purifying HK1 was used to undertake the purification of a second isoform (HK3). We were able to obtain preliminary results on its kinetic properties. Hexokinase Tubercule de pomme de terre Purification de protéine Caractérisation enzymatique Hexokinase Potato tuber Protein purification Protein characterization
19	Développement de biocapteurs pour la détermination de substances biologiquement actives / Development of biosensors for the determination of biologically active substances Kucherenko, Ivan 03 June 2016 (has links) Les biocapteurs sont des moyens d’analyse en plein essor à la fois rapides, sélectifs et peu coûteux applicables à des domaines extrêmement variés (environnement, santé, agroalimentaire,…). Dans ce type d’outil, un élément sensible de nature biologique (anticorps, enzyme, microorganisme, ADN…) doté d’un pouvoir de reconnaissance pour un analyte ou un groupe d’analytes est associé à un transducteur pouvant être de type électrochimique, optique ou thermique.Dans ce travail, nous nous sommes intéressés au développement de trois biocapteurs pour la détection de substances biologiquement actives. Le premier permet la détermination simultanée de l’adénosine triphosphate (ATP) et du glucose par ampérométrie, le deuxième celle de la créatine kinase, et le troisième est un biocapteur conductimétique pour la quantification de l’ATP. Dans les deux premiers biocapteurs, deux enzymes (l’hexokinase et la glucose oxydase) sont immobilisées à la surface de microélectrodes constituées d’un disque de platine. Le troisième biocapteur est basé sur l’immobilisation de l’hexokinase sur des microélectrodes interdigitées en or. L’immobilisation est réalisée dans tous les cas par co-réticulation des enzymes en présence d’albumine de sérum bovin à l’aide de glutaraldehyde. Les caractéristiques analytiques des biocapteurs ont été déterminées et différentes procédures ont été développées pour l’analyse d’échantillons réels. Les biocapteurs ont pu être appliqués avec succès à la quantification de l’ATP, du glucose et de la créatine kinase dans des préparations pharmaceutiques et du sérum sanguin / Biosensors are rapid, selective and inexpensive devices that combine a biological recognition element, the so-called bioreceptor (e.g. enzymes, antibodies, DNA or microorganisms) to a physical transducer (e.g. electrochemical, optical, thermal or piezoelectrical). They can be used to detect one specific analyte or one family of analytes for a wide range of applications (e.g. environment, food, health). In this work, the detection of biologically active substances was targeted. A biosensor system for simultaneous determination of adenosine triphosphate (ATP) and glucose, a biosensor for creatine kinase analysis, and a novel conductometric biosensor for ATP determination were developed. In the first two biosensors, two enzymes (hexokinase and glucose oxidase) were immobilized at the surface of platinum disc microelectrodes for amperometric detection. The third biosensor was based on hexokinase immobilized onto gold interdigitated microelectrodes for conductometric detection. In all cases, the enzymes were co-immobilized with bovine serum albumin by cross-linking using glutaraldehyde. Analytical characteristics of the biosensors were determined and different procedures were developed for real samples analysis. The biosensors could be successfully applied to the determination of ATP, glucose, and creatine kinase in pharmaceutical samples and blood serum Biocapteurs Ampérométrie Conductimétrie Enzymes immobilisées Glucose oxydase Hexokinase Adénosine triphosphate Glucose Biosensors Amperometry Conductometry Immobilized enzymes Glucose oxidase Hexokinase Adenosine triphosphate Glucose 660.6
20	Kinetic modelling of wine fermentations : why does yeast prefer glucose to fructose Mocke, Leanie 03 1900 (has links) Thesis (MSc)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: In the present-day competitive global market, wine industries are constantly aiming to improve the wine-making process,including the role of yeast. The most commonly used wine yeast is Saccharomyces cerevisiae, which is able to produce high quality wines, but problem fermentations do sometimes arise. The occurrence of stuck and sluggish fermentations pose a serious problem leading to loss of productivity and quality. Although the precise mechanism leading to stuck fermentations is unknown, they are often correlated with high fructose to glucose ratios in the wine-must. S. cerevisiae is a glucophylic yeast, indicating its preference for consuming glucose over fructose. Both these hexose sugars are present in unfermented wine must, mostly in equal concentrations. As fermentation progresses, glucose is consumed at a faster rate than fructose, leading to an increase in the fructose to glucose ratio. Yeast are left with the undesirable fructose at the later stages of fermentation, when the environmental stresses on the yeast can lead to stuck or sluggish fermentation. This residual fructose can lead to undesirable sweetness, as fructose is about twice as sweet as glucose. Even with the extensive research into yeast metabolism, there is as yet no definitive explanation as to why yeasts ferment glucose faster than fructose. This study aimed to investigate the mechanism responsible for the faster consumption of glucose over fructose of a commercially used wine yeast strain S. cerevisiae VIN 13. The first two steps of sugar metabolism, uptake and phosphorylation, were investigated as the possible sites of discrepancy in fermentation rates. Enzyme rates and affinities for both glucose and fructose as substrates for the relevant enzymes were experimentally determined. These kinetic parameter values were used to improve an existing model of yeast glycolytic pathway to model wine fermentations. The feasibility of constructing and validating a kinetic model of wine fermentations were investigated, by comparing model predicted fluxes with experimentally determined fluxes. Another aspect of this study was an investigation into the effect of hexose sugar type on fermentation profiles. Wine fermentations were done with only one hexose sugar as carbon source to determine if it has an effect on the flux through metabolism. This work succeeded in the construction of a kinetic model that distinguished between glucose and fructose as carbon source. The glucose was consumed faster than fructose, with control lying in the hexose transport step. It was also established that fermentation prfiles of fermentations with only one sugar was the same for both one sugar type fermentations. Fermentation with either glucose or fructose as the sole carbohydrate source had the same specfic production and consumption rates as normal fermentations with both sugars. Construction of detailed kinetic models can aid in the metabolic and cellular engineering of novel yeast strains. By identifying the importance of hexose transport, and thus the glucophilic character of the yeast, in flux control, yeast transporters can be targeted for strain improvement. This may in turn lead to more effective fermentation practices for controlling problem fermentations, or to the development of novel strains that utilizes fructose in the same manner as glucose, and in so doing lower the risk of stuck or sluggish wine fermentation. / AFRIKAANSE OPSOMMING: In die hedendaagse kompeterende wynmark is wynmakers aanhoudend besig om die wynmaak proses te verbeter en dit sluit die verbetering van wyngis in. Die mees algemeenste gebruikte wyngis is Saccharomyces cerevisiae, omdat dit wyn van gehalte produseer, maar probleem fermentasies kom wel voor. Die verskynsel van vasval of stadige fermentasies kan lei tot die verlies van produksie en kwaliteit. Die oorsaak van probleem fermentasies is gewoontlik veelvoudig, maar die verhouding van glukose tot fruktose in die wyn-mos kan ongunstig raak om fermentasies te onderhou. S. cerevisiae is 'n glukofiliese gis, wat sy voorkeur om glukose bo fruktose te gebruik beskryf. Albei hierdie heksose suikers is teenwoordig in ongefermenteerde wyn-mos, meestal in gelyke hoeveelhede. Soos fermentasies vorder word glukose vinniger verbruik as fruktose wat lei tot 'n toename in die fruktose tot glukose verhouding. Die gis moet dus die fruktose in die later stadium van fermentasie gebruik wanneer die omgewings druk op die gis kan lei tot probleem fermentasies. Die oorblywende fruktose kan lei tot ongewenste soetheid aangesien fruktose twee keer soeter is as glukose. Selfs met die ekstensiewe navorsing met betrekking tot gis metabolisme is daar nog nie 'n verduideliking hoekom gis glukose vinniger as fruktose gebruik nie. Hierdie studie het beoog om die meganisme wat lei tot die vinniger verbruik van glukose oor fruktose te ondersoek vir 'n kommersieël gebruikte gis S. cerevisiae VIN 13. Die eerste twee stappe van suiker metabolisme, suiker opname en fosforilasie, was ondersoek as die moontlike punt van die verskil in fermentasie tempo. Ensiem snelhede en affiniteite vir beide glukose en fruktose as substrate vir die ensieme van belang was eksperimenteel bepaal. Hierdie waardes is gebruik om 'n bestaande model van gis glikolise aan te pas vir wyn fermentasies. Die uitvoerbaarheid van saamstel en valideer van 'n kinetiese model van wyn fermentasies was ondersoek, deur model voorspelde fluksie waardes met eksperimentele fluksie waardes te vergelyk. 'n Ander aspek van die studie was die ondersoek van die effek van heksose suiker tipe op fermentasie profiel. Wyn fermentasies is gedoen met slegs een heksose suiker as koolstof bron om te bepaal of dit 'n invloed het op die fluksie deur metabolisme. Hierdie werk het daarin geslaag om 'n kinetiese model saamtestel wat onderskei tussen glukose en fruktose as koolstof bron. Die glukose is vinniger verbruik as fruktose, met beheer gesetel in die heksose opname stap. Dit was ook vasgestel dat fermentasie profiele van fermentasies met slegs een suiker nie verskil het vir fermentasies met slegs fruktose of glukose. Fermentasies met slegs een suiker het dieselfde spesifieke produksie en konsumpsie tempo gehad as die normale fermentasie met albei suikers. Die konstruksie van 'n gedetailleerde kinetiese model kan gebruik word in die metaboliese en sellulêre ontwikkeling van nuwe gisstamme. Deur die ontdekking van die belangrikheid van heksose opname in fluksie beheer, wat lei tot die glukofiliese karakter van gis, kan gis opname geteiken word vir gis ontwikkeling. Dit mag om die beurt lei tot meer effektiewe fermentasie praktyk in die beheer van probleem fermentasies, of die ontwikkeling van nuwe stamme wat fruktose in dieselfde manier as glukose benut, en sodoende die risiko van vasval of stadige wyn fermentasies verlaag. / National Research Foundation / Post-graduate Merit Bursary Wine fermentation Yeast hexokinase Wine and wine making -- Microbiology Glucokinase Dissertations -- Biochemistry Theses -- Biochemistry Biochemistry

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