Application of high pressure processing for extending the shelf-life of fresh lactic curd cheese

Daryaei, Hossein, s3088498@student.rmit.edu.au

January 2008

Outgrowth of spoilage yeasts and moulds and post-processing acidification can limit the shelf-life of some fermented dairy products including fresh lactic curd cheeses. The possibility of using high pressure processing (HPP) for controlling these problems was investigated in a commercially manufactured fresh lactic curd cheese (pH 4.3-4.4) and fermented milk models (pH 4.3-6.5). The effects of HPP at 300 and 600 MPa on inactivation of glycolytic enzymes of lactic acid bacteria were also evaluated. Fresh cheeses made from pasteurised bovine milk using a commercial Lactococcus starter preparation were treated with high pressures ranging from 200 to 600 MPa (less than or equal to 22°C, 5 min) under vacuum packaging conditions and subsequently stored at 4°C for 8 weeks. Treatment at greater than or equal to 300 MPa substantially reduced the viable count of Lactococcus and effectively prevented the outgrowth of yeasts and moulds for 6 to 8 weeks without adversely affecting the sensory and textural attributes of the product. However, it had no significant effects (p less than 0.01) on variation of titratable acidity during storage. Fermented milk models were prepared by individually growing Lactococcus lactis subsp. lactis C10, Lactococcus lactis subsp. cremoris BK5, Streptococcus thermophilus TS1, Lactobacillus acidophilus 2400 and Lactobacillus delbrueckii subsp. bulgaricus 2517 in UHT skim milk and diluting the resulting fermented milk with UHT skim milk up to pH 6.5. Pressure treatment of the milk models at pH 5.2 resulted in substantial inhibition of post-processing acidification during storage and markedly reduced the viable count of Lactococcus at both 300 and 600 MPa and other bacteria only at 600 MPa. Treatment of the milk model at 600 MPa decreased the viable counts of Candida zeylanoides and Candida lipolytica (wildtype spoilage yeasts of lactic curd cheese, added as challenge cultures) from 105 CFU mL-1 to below the detection limit (log 0 CFU mL-1) at all pH levels tested (pH 4.3-6.5) and effectively controlled their outgrowth for 8 weeks. Treatment of milk model at 300 MPa had a similar effect only on C. zeylanoides. The viable count of C. lipolytica was reduced by 2.6, 2.4 and 2.3 logs by treatment at 300 MPa at pH levels of 4.3, 5.2 and 6.5, respectively, which subsequently recovered by 2.9, 2.8 and 3.2 logs within 3 weeks. Glycolytic enzymes of various starter bacteria showed different responses to pressure treatment. The lactate dehydrogenase in L. lactis subsp. lactis and Lb. acidophilus was quite resistant to pressures up to 600 MPa, but it was almost completely inactivated in S. thermophilus at pressure levels as low as 300 MPa. The â-galactosidase in Lb. acidophilus was more pressure stable than â-galactosidase in S. thermophilus and Phospho-â-galactosidase in L. lactis subsp. lactis. The findings of this study suggests HPP at 300-600 MPa as an effective method for controlling the outgrowth of some spoilage yeasts and moulds in fresh lactic curd cheeses. The results obtained with selected lactic acid bacteria in fermented milk models can be used to assist in establishing HPP operating parameters for development of new generation cultured dairy products, of reduced acidity and extended shelf-life.

Fresh lactic curd cheese

Post-processing acidification

Shelf-life

High pressure processing

Glycolytic enzymes

Lactic acid bacteria

Yeasts and moulds

Patterns of protein expression in tissues of the killifish, Fundulus heteroclitus and Fundulus grandis

Abbaraju, Naga Vijayalaxmi

20 May 2011

Fundulus is a diverse and widespread genus of small teleost fish of North America. Due to its high tolerance for physiochemical variation (e.g. temperature, oxygen, salinity), Fundulus is a model organism to study physiological and molecular adaptations to environmental stress. The thesis focuses on patterns of protein expression in Fundulus heteroclitus and F. grandis.The patterns of protein expression were investigated using traditional methods of enzyme activity measurements and recent proteomic approaches. The findings of the study can be used to guide future studies on the proteomic responses of vertebrates to environmental stress. Chapter 2 focuses on measurement of the temporal effects of oxygen treatments on the maximal specific activities of nine glycolytic enzymes in liver and skeletal muscle during chronic exposure (28d) of Fundulus heteroclitus. The fish was exposed to four different oxygen treatments: hyperoxia, normoxia, moderate hypoxia, and severe hypoxia. The time course of changes in maximal glycolytic enzyme specific activities was assessed at 0, 8, 14 and 28 d. The results demonstrate that chronic hypoxia alters the capacity for carbohydrate metabolism in F. heteroclitus, with the important observation that the responses are both tissue- and enzyme-specific. Chapter 3 studies the effect of tissue storage on protein profile of tissues of F. grandis. The technique of one dimensional gel electrophoresis (1D-SDS-PAGE) was used to assess the effects of tissue sampling, flash frozen in liquid nitrogen versus immersion of fresh tissue in RNA later, for five tissues, liver, skeletal muscle, brain, gill, and heart, followed by LC-MS/MS to identify protein bands that were differentially stabilized in gill and liver. The study shows that, in F. grandis, the preferred method of preservation was tissue specific. xi Chapter 4 focuses on the use of advanced 2DE-MS/MS to characterize the proteome of multiple tissues in F. grandis. Database searching resulted in the identification of 253 non-redundant proteins in five tissues: liver, muscle, brain, gill, and heart. Identifications include enzymes of energy metabolism, heat shock proteins, and structural proteins. The protein identification rate was approximately 50 % of the protein spots analyzed. This identification rate for a species without a sequenced genome demonstrates the utility of F. grandis as a model organism for environmental proteomic studies in vertebrates.

Fundulus heteroclitus

Fundulus grandis

Hypoxia

Glycolytic enzyme specific activities

Protein expression

tissue storage

Proteomics

Fish

Mass Spectrometry

Liquid Chromatography

Gene Ontology

Analyse de la variabilité de l’expression génique et du métabolisme glycolytique au cours du processus de différenciation érythrocytaire : de l’analyse à grande échelle aux questions mécanistiques / Analysis of gene expression variability and glycolytic metabolism during the erythroid differentiation process : from high-throughput analysis to mechanistic issues

Richard, Angélique

06 April 2018

La prise de décision cellulaire se traduit par la capacité de toute cellule vivante à intégrer les différentes informations provenant de son environnement, et à les transformer en une réponse biologique cohérente. Il est aujourd'hui de plus en plus démontré que les populations cellulaires présentent une hétérogénéité quantitative et qualitative significative, qui pourrait jouer un rôle essentiel dans le fonctionnement des organismes vivants. La première partie de ma thèse a ainsi consisté à étudier la variabilité de l'expression génique au cours de la différenciation de progéniteurs érythrocytaires aviaires primaires, à l'échelle de la cellule unique. L'expression de 92 gènes a été analysée par RT-qPCR dans des cellules isolées à différents temps de différenciation. Les principaux résultats de cette étude ont montré que la variabilité de l'expression des gènes, mesurée par l'entropie de Shannon, atteint un niveau maximal à 8h-24h de différenciation, simultanément à une chute du nombre de gènes corrélés. Cette augmentation de la variabilité génique précède l'engagement irréversible des cellules dans le processus de différenciation érythrocytaire identifié entre 24 et 48h. Cette étude a également mis en lumière le gène LDHA (Lactate dehydrogenase A), codant pour une enzyme de la glycolyse anaérobie, dans les progéniteurs érythrocytaires en état d'auto-renouvellement et aux points critiques, 8h et 24h, de la différenciation. La deuxième partie de ma thèse a donc consisté à analyser le rôle précis de LDHA dans l'auto-renouvellement des progéniteurs érythrocytaires, ainsi que les variations du métabolisme du glucose au cours de la différenciation. Nos premiers résultats suggèrent que le processus de différenciation érythrocytaire s'accompagne d'un changement métabolique correspondant au passage de la glycolyse anaérobie dépendante de LDHA, vers une production d'énergie aérobie, reposant sur la phosphorylation oxydative / The meaning of cell decision making consists in the capacity of every living cell to integrate environmental information and to transform it in a coherent biological response. Nowadays it is increasingly demonstrated that cell populations present a significant quantitative and qualitative heterogeneity that could be involved in living organisms functions. Thus, the first part of my thesis consisted in studying gene expression variability at the single-cell level during the differentiation process of primary avian erythroid progenitor cells. The expression of 92 genes was analyzed using RT-qPCR in cells isolated at different differentiation time-points. The main results of this study showed that gene expression variability, as measured by Shannon entropy, reached a maximal level, simultaneously to a drop in the number of correlated genes, at 8-24h of differentiation. This increase of the gene expression variability preceded the irreversible commitment of cells into differentiation, identified between 24h and 48h. This analysis also highlighted the potential importance ofLDHA(Lactate dehydrogenase A) encoding a glycolytic enzyme, in erythroid progenitors self-renewal and at the critical differentiation time-point 8-24h. Therefore the second part of my thesis consisted in analyzing the role of LDHA in erythroid progenitors self-renewal and the variations of glucose metabolism during the differentiation process. Our first results suggested that erythroid differentiation might be accompanied with a metabolic change, corresponding to a switch from anaerobic glycolysisdepending upon LDHA, toward aerobic energy production, relying upon oxidative phosphorylation

Différenciation

Stochasticité de l'expression génique

Cellule unique

Métabolisme glycolytique

Lactate deshydrogénase A

Differentiation

Gene expression stochasticity

Single cell

Glycolytic metabolism

Lactate dehydrogenase A

570

Untersuchungen zur Validität und Praktikabilität des mathematisch bestimmten maximalen Laktat-steady-states bei radergometrischen Belastungen

Hauser, Thomas

27 February 2013

Das maximale Laktat-steady-state (MLSS) gilt als ein physiologischer Parameter der Ausdauerleistungsfähigkeit. Bereits in den 1980er Jahren entwickelte Mader (1984) auf Basis der Michaelis-Menten-Kinetik eine Berechnungsmethode zur Bestimmung der Leistung im MLSS. Diese Methode setzt die Kenntnis der maximalen Reaktionsgeschwindigkeiten von Glykolyse und Atmung voraus. Die Goldstandard-Methode zur Ermittlung der Leistung im MLSS sind mehrere 30-minütige konstante Dauerbelastungen. Das hauptsächliche Ziel der vorliegenden Arbeit bestand in dem Vergleich der berechneten mit der empirisch ermittelten Leistung im MLSS. 57 männliche Probanden unterzogen sich zunächst in randomisierter Reihenfolge einem Test zur Bestimmung der maximalen Laktatbildungsrate sowie der maximalen Sauerstoffaufnahme. Im Anschluss absolvierten die Testpersonen mehrere 30 minütige Dauertests zur empirischen Ermittlung der Leistung im MLSS. Die ermittelten Ergebnisse zeigen, dass zwischen beiden Testmethoden eine hochsignifikante Korrelation (r = 0,89; p< 0,001) sowie eine mittlere Differenz von -13 Watt vorliegt. Ausgehend von den ermittelten Ergebnissen kann der Schluss gezogen werden, dass die Leistung im MLSS, ermittelt unter Verwendung der Methode nach Mader (1984) im Mittel mit der empirisch ermittelten Leistung im MLSS sehr gut übereinstimmt. Neben der angeführten Hauptstudie, wurde in der vorliegenden Arbeit weiterhin die Reliabilität und Tag-zu-Tag-Variabilität der Leistung im MLSS, der Einfluss der Testdauer auf die Laktatbildungsrate sowie die Praktikabilität der berechneten Leistung im MLSS in einem Einzelzeitfahren näher untersucht.

maximales Laktat-steady-state

Ausdauerleistungsdiagnostik

maximale Laktatbildungsrate

maximale Sauerstoffaufnahme

maximal lactat-steady-state

endurance performance diagnostic

maximal glycolytic rate

ddc:790

Lactate

Ausdauerleistung

Sauerstoffaufnahme

Diagnostik

Structure-Function Studies On Triosephoshate Isomerase From Plasmodium falciparum And Methanocaldococcus jannaschii

Banerjee, Mousumi

04 1900

This thesis describes studies directed towards understanding structure-function relationships of triosephosphate isomerase (TIM), from a protozoan parasite Plasmodium falciparum and a thermophilic archaea Methanocaldococcus jannaschii. Triosephosphate isomerase, a ubiquitous glycolytic enzyme, has been the subject of biochemical, enzymatic and structural studies for the last five decades. Studies on TIM have been central to the development of mechanistic enzymology. The present study investigates the role of specific residues in the structure and function of Plasmodium falciparum triosephosphate isomerase (PfTIM). The structure and stability of a tetrameric triosephosphate isomerase from Methanocaldococcus jannaschii (MjTIM) is also presented. Chapter 1 provides a general introduction to the glycolytic enzyme triosephosphate isomerase, conservation of TIM sequences, its fold and three dimensional organization. The isomerisation reaction interconverting dihydroxyacetone phosphate and glyceraldehyde 3phosphate catalyzed by triosephosphate isomerase is an example of a highly stereospecific proton transfer process (Hall & Knowles, 1975; Rieder & Rose, 1959). This chapter briefly reviews mechanistic features and discusses the role of active site residues and the functional flexible loop 6. Triosephosphate isomerase adopts the widely occurring ( β/ α)8 barrel fold and mostly occurs as a dimer (Banner et al., 1975). Protein engineering studies, related to folding, stability and design of monomeric TIM are also addressed. A brief introduction to thermophilic TIMs and higher oligomeric TIMs is given. The role of this enzyme in disease states like hemolytic anemia and neuromuscular dysfunction is surveyed. The production of methylglyoxal, a toxic metabolite, as a byproduct of the TIM reaction is also considered. Many proteins utilize segmental motions to catalyze a specific reaction. The omega loop (loop 6) of triosephosphate isomerase is important for preventing the ene-diol intermediate from forming the cytotoxic byproduct, methylglyoxal. The active site loop-6 of triosephosphate isomerase moves about 7Ǻ on ligand binding. It exhibits a hinged lid motion alternating between two well defined, “open” and “closed”, conformations (Joseph et al., 1990). Though the movement of loop 6 is not ligand gated, in crystals the ligand bound forms invariably reveal a closed loop conformation. Plasmodium falciparum TIM is an exception which predominantly exhibits “open” loop conformations, even in the ligand bound state (Parthasarathy et al., 2002). Phe 96 is a key residue that is involved in contacts between the flexible loop-6 and the protein body in PfTIM. Notably, in all TIM sequences determined thus far, with the exception of plasmodial sequences, this residue is Ser 96. In Chapter 2 the mutants F96S, F96H and F96W are reported. The crystal structures of the mutant enzymes with or without bound ligand are described. In all the ligand free cases, loop-6 adopts an “open” conformation. Kinetic parameters for all the mutants establish that residue 96 does not play an essential role in modulating the loop conformation but may be important for ligand binding. Structural analysis of the mutants along with WT enzyme reveals the presence of a water network which can modulate ligand binding. Subunit interfaces of oligomeric proteins provide an opportunity to understand protein- protein interactions. Chapter 3 describes biochemical and biophysical studies on two separate dimer-interface destabilizing mutants C13E and W11F/W168F/Y74W of PfTIM. The intention was to generate a stable monomer by disrupting the interaction hubs. C13 is a part of a large hydrophobic patch (Maithal et al., 2002a) at the dimer interface. Introduction of a negative charge at position 13 destabilizes the interface and reduces activity. Y74 is a part of an aromatic cluster of the interface (Maithal et al., 2002b). The Y74W triple mutant was designed to disrupt the aromatic cluster by introducing additional atoms. Tryptophan is also a fluorophore, allowing studies of the dimer disruption by fluorescence, after mutating the two inherent tryptophan residues, W11 and W168 to phenylalanine. The mutants showed reduced activity and were more sensitive than the wild type enzyme to chemical denaturants as well as thermal denaturation. Evidenced for monomer formation is presented. These studies together with previous work reveal that the interface is important for both activity and stability. In order to develop a model for understanding the relationship between protein stabilization and oligomeric status, characterization of the TIM from Methanocaldococcus jannaschii (MjTIM) has been undertaken. Chapter 4 describes the purification and characterization of MjTIM. The MjTIM gene was cloned and expressed in pTrc99A and protein was isolated from AA200 E. coli cells. Hyperexpressed protein was purified to homogeneity and relevant kinetic parameters have been determined. The tetrameric nature of MjTIM is established by gel filtration studies. Circular dichroism (CD) studies establish the stability of the overall fold, even at temperatures as high as 95ºC. A surprising loss of enzyme activity upon prolonged incubation at high temperature was observed. ESI-MS studies establish that oxidation of thiol groups of the protein may be responsible for the thermal inactivation. Chapter 5 describes the molecular structure of MjTIM, determined in collaboration with Prof. MRN Murthy’s group at the Indian Institute of Science (Gayathri et al., 2007). The crystal structure of the recombinant triosephosphate isomerase (TIM) from the archaeabacteria Methanocaldococcus jannaschii has been determined at a resolution of 2.3 Å. MjTIM is tetrameric, as suggested by solution studies and from the crystal structure, as in the case of two other structurally characterised archaeal TIMs. The archaeabacterial TIMs are shorter compared to the dimeric TIMs, with the insertions in the dimeric TIMs occurring in the vicinity of the putative tetramer interface, resulting in a hindrance to tetramerization in the dimeric TIMs. The charge distribution on the surface of archaeal TIMs also facilitates tetramerization. Analysis of the barrel interactions in TIMs suggests that these interactions are unlikely to account for the thermal stability of archaeal TIMs. A feature of the unliganded structure of MjTIM is the complete absence of electron density for the loop 6 residues. The disorder of the loop may be ascribed to a missing salt bridge between residues at the N- and C- terminal ends of the loop in MjTIM. Chapter 6 is a follow up of an interesting observation made by Vogel and Chmielewski (1994), who noticed that subtilisin cleaved rabbit muscle triosephosphate isomerase religated spontaneously upon addition of organic solvents. Further extension of this nicking and religation process with PfTIM emphasizes the importance of tertiary interactions in contributing to the stability of the (β/α)8 barrel folds (Ray et al., 1999). This chapter establishes that subtilisin nicking and religation is also facile in thermophilic MjTIM. Fragments generated by subtilisin nicking were identified using MALDI mass spectrometry at early and late stages of the cleavage for both the dimeric PfTIM and tetrameric MjTIM. This chapter also describes the comparative thermal and denaturant stability of both the enzymes. The accessibility of the Cys residues of MjTIM has been probed by examining the rates of labeling of thiol groups by iodoacetamide. The differential labeling of Cys residues has been demonstrated by mass spectrometry. Chapter 7 summarizes the main results and conclusions of the studies described in this thesis.

Metabolism Function (Biology)

Plasmodium falciparum

Triosephosphate Isomerase

Methanocaldococcus jannaschii

Glycolytic Enzymes

Mutagenesis

Ligand Binding

Enzymes - Purification

Enzymes - Structure

Enzyme Kinetics

Enzymology

Études de la réponse du métabolisme énergétique à la carence en fer dans les cultures cellulaires de Solanum tuberosum

Canelo Vivar, Marcela Paz

07 1900

Le fer est un micronutriment important pour la croissance et le développement des plantes. Il agit comme cofacteur pour plusieurs enzymes et il est important pour des processus tels que la photosynthèse et la respiration. Souvent, le Fe dans le sol n’est pas bio-disponible pour la plante. Les plantes ont développé des stratégies pour solubiliser le Fe du sol pour le rendre disponible et assimilable pour elles. Il y a deux stratégies, la première est caractéristique des dicotylédones et la seconde est caractéristique des monocotylédones. Le modèle utilisé dans cette étude est une culture cellulaire de Solanum tuberosum. Une partie de la recherche effectuée a permis la mesure d’activité et d’expression relative de certaines enzymes impliquées dans le métabolisme énergétique et la fourniture de précurseurs pour la synthèse d’ADN : la Nucléoside diphosphate kinase, la Ribonucléotide reductase, la Glucose 6-phosphate déshydrogénase et la 6-Phosphogluconate déshydrogénase dans les cellules en présence ou en absence de Fe. Chez certains organismes, la déficience en Fe est associée à une perte de croissance qui est souvent liée à une diminution de la synthèse d’ADN. Chez les cultures de cellules de S. tuberosum, les résultats indiquent que la différence de biomasse observée entre les traitements n’est pas due à une variation de l’activité ou l’expression relative d’une de ces enzymes. En effet, aucune variation significative n’a été détectée entre les traitements (+/- Fe) pour l’activité ni l’expression relative de ces enzymes. Une autre partie de la recherche a permis d’évaluer l’activité des voies métaboliques impliquées dans la stratégie 1 utilisée par S. tuberosum. Cette stratégie consomme des métabolites énergétiques: de l’ATP pour solubiliser le Fe et du pouvoir réducteur (NAD(P)H), pour réduire le Fe3+ en Fe2+. Des études de flux métaboliques ont été faites afin d’étudier les remaniements du métabolisme carboné en déficience en Fe chez S. tuberosum. Ces études ont démontré une baisse du régime dans les différentes voies du métabolisme énergétique dans les cellules déficientes en Fe, notamment dans le flux glycolytique et le flux de C à travers la phosphoenolpyruvate carboxylase. En déficience de Fe il y aurait donc une dépression du métabolisme chez S. tuberosum qui permettrait à la cellule de ralentir son métabolisme pour maintenir sa vitalité. En plus des flux, les niveaux de pyridines nucléotides ont été mesurés puisque ceux-ci servent à réduire le Fe dans la stratégie 1. Les résultats démontrent des niveaux élevés des formes réduites de ces métabolites en déficience de Fe. L’ensemble des résultats obtenus indiquent qu’en déficience de Fe, il y a une baisse du métabolisme permettant à la cellule de s’adapter et survivre au stress. / Iron is an important micronutrient for plant growth and development. It participates as a cofactor for several enzymes and is important for processes such as photosynthesis and respiration. Often soil Fe is not bioavailable to the plant. Plants have developed strategies to solubilize the Fe in the soil to make it available and easy to assimilate. There are two strategies, the first is characteristic of dicotyledones and the second is characteristic of monocotyledones. The model used in these studies is a cell culture of Solanum tubersoum. A first part of the research involved the study of expression and activity of enzymes required in energy metabolism and the provision of precursors for DNA synthesis: Nucleoside dehydrogenase, Ribonucleotide reductase, Glucose 6-phohate dehydrogenase and 6-Phosphogluconate dehydrogenase. In several organisms, Fe deficiency induces a loss of biomass which is often associated with a decrease in DNA synthesis. In S. tuberosum cell cultures, the results indicate that the loss of biomass observed in Fe deficiency is not linked to a change in the activity or relative expression of these enzymes. Indeed, no significant changes were detected between treatments (+/- Fe) for activity or relative expression. In another part of the research, we evaluated the activity of the metabolism pathways involved in strategy 1, which is used by S. tuberosum. This strategy consumes energetic metabolites: ATP to solubilize Fe and reducing power (NAD(P)H) to reduce the Fe3+ to Fe2+. Metabolic flux studies were done to investigate the alterations of carbon metabolism during Fe deficiency in S. tuberosum. These studies demonstrated that in Fe deficient cells, there is a decrease in the fluxes of some pathways of energy metabolism. Particularly, in the glycolytic flux and the anaplerotic flux of PEPC. Under Fe deficiency there would be a depression of metabolism in S. tuberosum which would allow the cell to slow its metabolism to maintain its vitality. In addition to the fluxes, the levels of pyridine nucleotides were measured since they serve to reduce Fe in the strategy 1. The results show an increase in the reduced forms of these metabolites during Fe deficiency. All results together point out that during Fe deficiency the metabolism decreases, allowing the cell to survive and adapt to the stress.

Solanum tuberosum

Culture cellulaire

Fer

Déficience

Stress

Métabolisme carboné

Métabolisme énergétique

Flux glycolytique

Flux anaplérotique

Cell culture

Iron

Carbon metabolism

Energetic metabolism

Deficiency

Glycolytic flux

Anaplerotic flux

Bioconversão de sacarose em ácido glicônico e frutose usando reator com membrana / Sucrose bioconversion into gluconic acid and fructose using a membrane reactor

Tomotani, Ester Junko

27 March 2006

A conversão enzimática da sacarose pela ação sucessiva da invertase e da glicose oxidase (GOD), permite obter produtos de maior valor agregado, a saber, frutose e o ácido glicônico, dois produtos de amplo uso na indústria farmacêutica, alimentícia e química. Foi estudada a aplicação da invertase imobilizada em resinas aniônicas do tipo Dowex&#174; (um copolímero de poliestireno-divinilbenzeno) sobre a hidrólise da sacarose bem como a oxidação da glicose pela glicose oxidase solúvel ou imobilizada no mesmo suporte em separado (sistema bifásico), utilizando-se um reator de membrana acoplado à membrana de ultrafiltração (100kDa) ou de microfiltração (5&#181;m). Posteriormente, avaliou-se o desempenho de ambas as formas de enzimas, solúveis ou imobilizadas num sistema monofásico empregando o mesmo reator. A bioconversão executada em sistema bifásico permitiu a obtenção de xarope de frutose da ordem de 70% através da separação de glicose e frutose utilizando-se a resina catiônica 50W:8-100. O rendimento de 96,6% e 67,4% para as formas solúveis e imobilizadas respectivamente foram obtidas em sistema monofásico. O não desprendimento das enzimas dos suportes viabilizou o uso da membrana de microfiltração, trazendo vantagens à operação de biorreator com membrana. / The enzymatic conversion of sucrose through a successive action of invertase and glucose oxidase (GOO) allows the obtainment of products with higher commercial value, fructose and gluconic acid, which are widely used in pharmaceutical, food and chemical industries. Invertase and GOO immobilized on Dowex&#174; anionic resin (a polystyrene divinylbenzene copolymer) as well as soluble GOD were used in a membrane bioreactor (MS) for sucrose hydrolysis and glucose oxidation. The MB was coupled with a UF-membrane (100kDa) or a MF-membrane (5&#181;m). The bioconversion was conducted in two steps (biphasic system) as well as in one step (monophasic system). The bioconversion operated in a biphasic system permitted obtaining a fructose syrup with a concentration of about 70% through a separation of glucose and fructose using a cationic resin, 50W:8-100. As for the monophasic system, the yield of 96.6% and 67.4% for soluble and immobilized forms were attained respectively. No leakage of the enzymes from the support allowed the use of a microfiltration membrane, adding advantages to the membrane bioreactor operation.

Anion resin

Biochemical reactors

Bioreator de membrana

Biotechnology

Biotecnologia

Enzima imobilizada

Enzimas glicolíticas (Uso)

Glicose oxidase

Glucose oxidase

Glycolytic Enzymes (Use)

Immobilized enzyme

Invertase

Invertase

Membrane bioreactor

Reatores bioquímicos

Resina aniônica

Sacarose

Sucrose

Bioconversão de sacarose em ácido glicônico e frutose usando reator com membrana / Sucrose bioconversion into gluconic acid and fructose using a membrane reactor

Ester Junko Tomotani

27 March 2006

A conversão enzimática da sacarose pela ação sucessiva da invertase e da glicose oxidase (GOD), permite obter produtos de maior valor agregado, a saber, frutose e o ácido glicônico, dois produtos de amplo uso na indústria farmacêutica, alimentícia e química. Foi estudada a aplicação da invertase imobilizada em resinas aniônicas do tipo Dowex&#174; (um copolímero de poliestireno-divinilbenzeno) sobre a hidrólise da sacarose bem como a oxidação da glicose pela glicose oxidase solúvel ou imobilizada no mesmo suporte em separado (sistema bifásico), utilizando-se um reator de membrana acoplado à membrana de ultrafiltração (100kDa) ou de microfiltração (5&#181;m). Posteriormente, avaliou-se o desempenho de ambas as formas de enzimas, solúveis ou imobilizadas num sistema monofásico empregando o mesmo reator. A bioconversão executada em sistema bifásico permitiu a obtenção de xarope de frutose da ordem de 70% através da separação de glicose e frutose utilizando-se a resina catiônica 50W:8-100. O rendimento de 96,6% e 67,4% para as formas solúveis e imobilizadas respectivamente foram obtidas em sistema monofásico. O não desprendimento das enzimas dos suportes viabilizou o uso da membrana de microfiltração, trazendo vantagens à operação de biorreator com membrana. / The enzymatic conversion of sucrose through a successive action of invertase and glucose oxidase (GOO) allows the obtainment of products with higher commercial value, fructose and gluconic acid, which are widely used in pharmaceutical, food and chemical industries. Invertase and GOO immobilized on Dowex&#174; anionic resin (a polystyrene divinylbenzene copolymer) as well as soluble GOD were used in a membrane bioreactor (MS) for sucrose hydrolysis and glucose oxidation. The MB was coupled with a UF-membrane (100kDa) or a MF-membrane (5&#181;m). The bioconversion was conducted in two steps (biphasic system) as well as in one step (monophasic system). The bioconversion operated in a biphasic system permitted obtaining a fructose syrup with a concentration of about 70% through a separation of glucose and fructose using a cationic resin, 50W:8-100. As for the monophasic system, the yield of 96.6% and 67.4% for soluble and immobilized forms were attained respectively. No leakage of the enzymes from the support allowed the use of a microfiltration membrane, adding advantages to the membrane bioreactor operation.

Bioreator de membrana

Biotecnologia

Enzima imobilizada

Enzimas glicolíticas (Uso)

Glicose oxidase

Invertase

Reatores bioquímicos

Resina aniônica

Sacarose

Anion resin

Biochemical reactors

Biotechnology

Glucose oxidase

Glycolytic Enzymes (Use)

Immobilized enzyme

Invertase

Membrane bioreactor

Sucrose

Tvorba proteinových granulí v diferencovaných buňkách kvasinkových kolonií / Formation of protein granules in differentiated cells of yeast colonies

Kočířová, Eliška

January 2020

Saccharomyces cerevisiae is a unicellular eukaryotic organism capable of forming organized multicellular communities - colonies and biofilms. During development, colonies of laboratory strains differentiate into specifically localized cell subpopulations - U and L cells, located in the upper and lower part of the colony, respectively. The U and L subpopulations of cells vary in morphology, metabolic processes and stress resistance. Protein granules are membrane-less "organelles" found in both unicellular and multicellular eukaryotic organisms. The formation of protein granules is related to the physiological state of the cell (e.g. chronological and replicative aging), but also to changing environmental conditions and to cellular responses to stress factors. A relatively large fraction of proteins relocalizes to some type of protein granule during the lifespan of the cell. Granule formation can increase fitness of cells, help them to cope with limiting energy resources, and plays a crucial role in the adaptation of cells to stress conditions. Localization of many proteins in the cell varies depending on its physiology. Therefore the specific localization of such proteins may be considered as a "marker" of a specific physiological condition. There are proteins in each type of granule that can be...

Untersuchungen zur Validität und Praktikabilität des mathematisch bestimmten maximalen Laktat-steady-states bei radergometrischen Belastungen

Hauser, Thomas

30 January 2013

Das maximale Laktat-steady-state (MLSS) gilt als ein physiologischer Parameter der Ausdauerleistungsfähigkeit. Bereits in den 1980er Jahren entwickelte Mader (1984) auf Basis der Michaelis-Menten-Kinetik eine Berechnungsmethode zur Bestimmung der Leistung im MLSS. Diese Methode setzt die Kenntnis der maximalen Reaktionsgeschwindigkeiten von Glykolyse und Atmung voraus. Die Goldstandard-Methode zur Ermittlung der Leistung im MLSS sind mehrere 30-minütige konstante Dauerbelastungen. Das hauptsächliche Ziel der vorliegenden Arbeit bestand in dem Vergleich der berechneten mit der empirisch ermittelten Leistung im MLSS. 57 männliche Probanden unterzogen sich zunächst in randomisierter Reihenfolge einem Test zur Bestimmung der maximalen Laktatbildungsrate sowie der maximalen Sauerstoffaufnahme. Im Anschluss absolvierten die Testpersonen mehrere 30 minütige Dauertests zur empirischen Ermittlung der Leistung im MLSS. Die ermittelten Ergebnisse zeigen, dass zwischen beiden Testmethoden eine hochsignifikante Korrelation (r = 0,89; p< 0,001) sowie eine mittlere Differenz von -13 Watt vorliegt. Ausgehend von den ermittelten Ergebnissen kann der Schluss gezogen werden, dass die Leistung im MLSS, ermittelt unter Verwendung der Methode nach Mader (1984) im Mittel mit der empirisch ermittelten Leistung im MLSS sehr gut übereinstimmt. Neben der angeführten Hauptstudie, wurde in der vorliegenden Arbeit weiterhin die Reliabilität und Tag-zu-Tag-Variabilität der Leistung im MLSS, der Einfluss der Testdauer auf die Laktatbildungsrate sowie die Praktikabilität der berechneten Leistung im MLSS in einem Einzelzeitfahren näher untersucht.

info:eu-repo/classification/ddc/790

ddc:790