Spelling suggestions: "subject:"osmotic stress"" "subject:"smotic stress""
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Interakce proteinů Whi3 a Yap6 při mírném osmotickém stresu / Interaction of Whi3 and Yap6 under mild osmotic stressVoloshin, Danila January 2021 (has links)
Natural strains of the Saccharomyces cerevisiae growing on solid médium form structured, biofilm -like colonies. This ability is depended on the surface adhesin Flo11p. The expression of the FLO11 gene is upregulated by the RNA-binding protein Whi3p, which is likely to have a negative effect on the level of the transcription factor Yap6p. The aim of this study was to determine whether Yap6p affects colony morphology and FLO11 expression. Analysis of FLO11 expression using the fluorescent proteins pFlo11-GFP and Flo11p-DsRed in WHI3-deletion strains demonstrated a negative effect of Yap6p on FLO11 expression and confirmed changes in the effect of Yap6p on FLO11 expression in the presence of NaCl. In the strain overexpressing YAP6, the fluorescence values of pFlo11-GFP and Flo11p-DsRed were lower than in the strain with deletion of the YAP6 and in the presence of NaCl there was observed the largest increase in fluorescence. Although Yap6 protein is thought to have a negative effect on FLO11 expression under standard culture conditions, it seems to be responsible for a significant increase in FLO11 expression in the presence of mild osmotic stress. In WHI3-deletion strains, there was observed a significant increase in structuredness of colonies growing in the presence of NaCl. Analysis of structured...
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Characterization and physiological role of aquaporins during desiccation and freezing in <i>Eurosta solidaginis</i>Philip, Benjamin N. 06 August 2010 (has links)
No description available.
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Aumento da tolerância de Saccharomyces cerevisiae a fatores estressantes da fermentação etanólica: linhagens modificadas e suplementação de aminoácidos / Increasing Saccharomyces cerevisiae tolerance to stressing factors of ethanolic fermentation: modified strains and amino acid supplementationVarize, Camila de Souza 15 January 2018 (has links)
O aumento da participação dos biocombustíveis na matriz energética mundial pode ajudar a prolongar a existência das reservas de petróleo, mitigar as ameaças representadas pela mudança climática e permitir melhor segurança do fornecimento de energia em uma escala global. Neste cenário, o processo brasileiro da produção de etanol a partir da cana-de-açúcar tem ganhado papel de destaque, pelo alto rendimento e baixo custo da produção. Linhagens de S. cerevisiae são amplamente empregadas nas fermentações industriais e, embora sejam consideradas mais tolerantes em relação a outras, o processo brasileiro impõe uma variedade de fatores estressantes sob a mesma, afetando o seu metabolismo e crescimento. A fermentação com alto teor alcoólico, realizada a partir da utilização de mostos contendo altas concentrações de açúcares, é uma das maneiras mais eficientes de se obter elevados níveis de etanol. No entanto, tal tecnologia procede ocasionando efeitos deletérios adicionais à levedura. Neste contexto, aumentar a tolerância da levedura é de fundamental importância para alcançar um desempenho fermentativo satisfatório. Neste estudo foram avaliadas linhagens de S. cerevisiae, isogênicas a linhagem industrial CAT-1, com a sobre-expressão dos genes TRP1 e MSN2, envolvidos na biossíntese de triptofano e na resposta geral ao estresse, respectivamente. Tais linhagens foram avaliadas quanto ao seu potencial para realizar fermentações com alto teor alcoólico, simulando as condições industriais brasileiras. Os resultados revelaram que o gene MSN2, na versão truncada, favoreceu a linhagem principalmente com relação ao estresse osmótico, aumentando a velocidade de fermentação e o consumo de açúcares. O gene TRP1 promoveu maior crescimento da linhagem em meio YEPD com 8% de etanol, contudo, tornou a linhagem menos viável em concentrações acima deste nível. No presente trabalho também foi avaliado o efeito da suplementação de aminoácidos na fisiologia da linhagem CAT-1 em meio YNB e em mostos de melaço e xarope de cana-de-açúcar. A suplementação com histidida promoveu maior crescimento e viabilidade celular nos diferentes meios testados. Além de histidina, os aminoácidos lisina e alanina aumentaram o crescimento da CAT-1 em mosto de melaço. A suplementação de triptofano e asparagina também promoveu aumento da viabilidade celular em mosto de xarope. Por outro lado, nos testes em microplacas a suplementação com cisteína depreciou o crescimento da linhagem em meio YNB com 10 e 12% de etanol e em mosto de melaço com 20% de ART. Os resultados obtidos indicam que tanto a engenharia genética, quanto a suplementação de aminoácidos podem ser alternativas viáveis para aumentar a tolerância de S. cerevisiae, para suportar condições de múltiplo estresse, encontradas em destilarias brasileiras. / The expansion biofuels participation in the world energy matrix would help to extend the existence of fossil fuel reservoirs, mitigate the threats of climate change, and enable a better security of energy supply. The Brazilian process of ethanol production from sugarcane has gained an important role in the global energy scenario, for the high yield and low production cost. S. cerevisiae species is widely used in industrial fermentations for being resistant, but the Brazilian process imposes a variety of stressing factors to the yeast, affecting its metabolism and growth. The Very High Gravity Fermentation is performed by the utilization of musts with high sugar concentration and is one of the most efficient ways for obtaining high ethanol levels. However, this technology causes additional deleterious effects to the yeast. In this context, increasing yeast tolerance is of fundamental importance for a satisfactory fermentative performance. In this study we assessed S. cerevisiae strains - isogenic to the industrial strain CAT-1 - with over expression of TRP1 and MSN2 genes involved to tryptophan biosynthesis and in general stress response, respectively. These strains were evaluated for their potential to perform fermentations with high ethanol content, simulating the conditions of Brazilian distilleries. The results showed that the MSN2 gene in the truncated version improved strain mainly to respond to the osmotic stress, increasing in fermentation velocity and the consumption of sugars. The TRP1 gene overexpression promoted higher growth in YEPD medium with 8% ethanol, however, decreased viability at concentrations above this level. The present work also evaluated the effect of amino acid supplementation on the physiology of the CAT-1 strain in YNB medium and in molasses and syrup of sugarcane. Histidide supplementation increased the growth and cell viability in the different media tested. In addition to histidine, the amino acids lysine and alanine increased the growth of CAT-1 in molasses. Supplementation of tryptophan and asparagine also promoted increased cell viability in sugarcane syrup. On the other hand, in microplate assays, cysteine supplementation decreased growth in YNB medium with 10 and 12% ethanol, and in molasses with 20% ART. The results indicate that both genetic engineering and amino acid supplementation may be viable alternatives to increase tolerance of S. cerevisiae to supporting multiple stress conditions typical in Brazilian distilleries.
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Estudo da expressÃo dos genes das bombas de prÃtons (V-ATPase e V-PPase) e dos contra-transportadores vacuolares (NHX) de Vigna unguiculata (L.) Walp submetidos a estresses abiÃticos / Expression study of proton pumps(V-ATPase and V-PPase) and vacuolar antiport (NHX) genes from Vigna unguiculata (L.) Walp submitted to abiotic stressAlana CecÃlia de Menezes Sobreira 27 July 2009 (has links)
CoordenaÃÃo de AperfeiÃoamento de Pessoal de NÃvel Superior / O acÃmulo de Na+ no vacÃolo central representa um importante mecanismo de defesa de plantas contra o estresse salino. A regulaÃÃo dos volumes e conteÃdos dos vacÃolos de cÃlulas vegetais depende da atividade de transportadores e canais localizados no tonoplasto (membrana vacuolar). A membrana vacuolar possui duas distintas bombas de prÃtons (V-ATPase e V-PPase), aquoporinas e vÃrios sistemas de transportes ativos e/ou secundÃrios, como os contra-transportadores Na+/H+ vacuolares. As duas bombas de prÃtons transmembranares funcionam como sistemas de transporte primÃrio nas cÃlulas vegetais e ambas as enzimas geram uma diferenÃa de potencial eletroquÃmico de prÃtons atravÃs da membrana vacuolar. Os contra-transportadores vacuolares Na+/H+ utilizam o gradiente eletroquÃmico de prÃtons gerado pelos transportadores primÃrios para transportar Na+ para dentro do vacÃolo. No presente trabalho inicialmente foram determinados os conteÃdos de Ãons Na+ e K+ em raÃzes, hipocÃtilos e folhas e em seguida a anÃlise da expressÃo dos genes das bombas de prÃtons (VHA-A, VHA-E e HVP) e dos contra-transportadores vacuolares (NHX2 e NHX6) em plÃntulas de Vigna unguiculata (L.) Walp cv. Vita 5 submetidas a estresse salino e osmÃtico. As plÃntulas foram crescidas em meio nutritivo na ausÃncia de NaCl e PEG (controle), na presenÃa de 100 mM de NaCl (estresse salino) ou na presenÃa de 200,67 g/L de PEG (estresse osmÃtico). O conteÃdo de Ãons Na+ aumentou em todos os tecidos da planta quando submetidos ao estresse salino (NaCl 100 mM) enquanto que o conteÃdo de Ãons K+ diminuiu na mesma condiÃÃo. A expressÃo dos genes das bombas de prÃtons e dos contra-transportadores vacuolares de folhas e de raÃzes no estresse salino aumentou em todas as condiÃÃes estudadas, porÃm o aumento foi mais expressivo para os genes da V-PPase, NHX2 e NHX6 sugerindo uma regulaÃÃo paralela entre esses genes. JÃ no estresse osmÃtico, os resultados para as folhas mostraram que a expressÃo dos genes VHA-A e VHA-E aumentaram enquanto que os outros genes nÃo sofreram mudanÃas significativas. Nossos resultados sugerem que o estresse salino e o estresse osmÃtico induziram uma regulaÃÃo diferenciada em todos os genes sendo o contra-transportador Na+/H+ importante na homeostase celular quando as plantas foram submetidas ao estresse salino e osmÃtico. / The acummulation of Na+ in the central vacuole represents an important mechanism for plants to cope with salt stress. The vacuolar content and the regulations of their volumes in vegetable cells depend on the activity of transporters and channels located in the tonoplast (vacuolar membrane). The vacuolar membrane possesses two different proton pumps (V-ATPase and V-PPase), aquoporine, and systems of primary and secondary transporters like the vacuolar Na+/H+ antiporter (NHX). The two transmembrane proton pumps work as systems of primary transport in vegetable cells and both enzymes generate a difference of proton electrochemical potential through the vacuolar membrane which can provide energy to antiport system, H+/substrate. The vacuolar Na+/H+ antiporter, uses the electrochemical gradient generated by the primary transporters to pump Na+ ions inward the vacuole. In the present work were first determined the Na+ and K+ content followed by the gene expression of the vacuolar proton pumps (VHA-A, VHA-E and HVP) and the vacuolar antiporters (NHX2 and NHX6) from seedlings of Vigna unguiculata subjected to salt and osmotic stress. The seedlings were grown on nutritive medium in the absence of NaCl and PEG (control condition), presence of NaCl 100 mM (salt stress) or in the presence of PEG 6000 200,67g.L-1 (osmotic stress). The ion Na+ content essay showed an increase in all plant tissues when submitted to salt stress, while the K+ ions decreased in the same condition. The gene expression of the vacuolar proton pumps and the Na+ antiporter from roots and leaves showed an increase in all studied conditions being more expressive to V-PPase, NHX2 and NHX6 suggesting a coordinated regulation of these genes. The results from leaves showed that VHA-A and VHA-E were increased, while the others genes tend to remain constant in the osmotic stress. These results suggest that salt and osmotic stress induced a differential regulation of all studied genes, being the vacuolar Na+ antiporters an important part on keep the cellular homeostasis when the plants were submitted to salt stress
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Heterologous Expression, Characterization, And Optimization Of Production Of Alpha-galactosidase From Aspergillus Fumigatus In Aspergillus SojaeGurkok, Sumeyra 01 October 2012 (has links) (PDF)
&alpha / -Galactosidase is an exo-glycosidase that hydrolyses non-reducing, &alpha / -1,6-linked &alpha / -galactose units from oligosaccharides, galactomannans, and galactolipids. &alpha / -Galactosidase activity has biotechnological, industrial, and medical importance. &alpha / -Galactosidase from A. fumigatus IMI 385708, in particular, can catalyse unique hydrolysis and transgalactosylation reactions on polymeric substrates. In this study, &alpha / -galactosidase of the human pathogen A. fumigatus IMI 385708 was first produced in a GRAS organism, Aspergillus sojae. For this aim, &alpha / -galactosidase gene (aglB) of A. fumigatus IMI 385708 was ligated onto pAN52-4 vector (Acc. No: Z32699) and transformed into Aspergillus sojae ATCC11906, under the control of the constitutive glyceraldehyde-3-phosphate dehydrogenase promoter (gpdA) of A. nidulans and the signal sequence of glucoamylase gene (glaA) of A. niger. This allowed high level of &alpha / -galactosidase production on glucose instead of locust bean gum (2.45 U/mL), corresponding to a 3-fold increase in volumetric production. Next, using response surface methodology, carbon and nitrogen sources and agitation speed were optimized (10.5% molasses (w/v) / 1.3% NH4NO3 (w/v) / 276 rpm). Compared to non-optimized cultivation, a further 4-fold increase in &alpha / -galactosidase production (10.4 U/mL) was achieved. Recombinant &alpha / -galactosidase was purified 18.7-fold using Anion Exchange and Hydrophobic Interaction Chromatography with an overall yield of 56% and 64.7 U/mg protein. The Vmax and Km values for the hydrolysis of p-nitrophenyl &alpha / -D-galactopyranoside were 78 U/mg protein and 0.45 mM, respectively. Optimum pH and temperature for &alpha / -galactosidase activity were between pH 4&ndash / 6 and 50&ndash / 60 ° / C, respectively. Among the tested chemical agents, Ag+, Hg2+, and Fe2+ drastically decreased the activity, while biotin, I+1, Mn+2, Pb+2, Li+1, and Mg+2 enhanced between 12&ndash / 29%. To analyse the influence of osmotic stress as a means of further inducing &alpha / -galactosidase production, salt was added into the complete growth medium. In addition to enzyme production, fungal growth and morphology were analysed for both &lsquo / salt-adapted&rsquo / and &lsquo / salt non-adapted&rsquo / A. sojae Ta1 cells in the presence of KCl, MgCl2, MgSO4, NaCl, and Na2SO4 at 1 M and 2 M. Accordingly, 3-fold increase in &alpha / -galactosidase production was achieved by non-adapted cells in the presence of 1 M NaCl. Exposure of A. sojae Ta1 cells to salt resulted in predominantly mycelial form, rather than the pellet form observed under normal conditions. Finally, the transgalactosylation ability of &alpha / -galactosidase was studied. &alpha / -Galactosidase efficiently catalysed galactose transfer to different monosaccharides and disaccharides in the presence of pNP&alpha / Gal as monitored by TLC, ESI-MS, and HPLC.
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Regulatory role of the mechanistic target of Rapamycin (mTOR) on the expression of osmotic stress response genes in mammalian cellsOrtells Campos, Mª Carmen, 1984- 26 July 2012 (has links)
Adaptive responses allow cells to maintain their growth as well as their proliferative potential under diverse stress conditions. It is known that, growth and proliferation can be suppressed by intense stress, but maintained under tolerable stress conditions under which cells can induce compensatory responses. The kinase mTOR is a central regulator of proliferative and growing capacity in mammalian cells, and has been shown to be sensitive to diverse stressors. However, little is known about the role played by mTOR in the adaptive responses that cells utilize to resist stress and maintain their growth capacity. We addressed this question in the context of osmotic stress, to which cells can adapt by inducing the transcription of specialized genes. We showed that mTOR is active under moderate osmostress conditions and regulates the induction of a set of genes by mechanisms dependent and independent of NFAT5, the main transcription factor involved in the transcription of genes upon hypertonic stress. In addition, we observed that the overall set of genes whose induction was sensitive to mTOR activity is enriched in regulators of growth and proliferation. We also have identified REDD1 and REDD2 as two osmostress and mTOR-dependent induced genes, which previously had been characterized in other stress contexts acting as negative regulators of the mTORC1 pathway. We observed that mTOR promoted changes in chromatin predisposing it towards a transcriptional permissive configuration, with higher levels of acetylated histone H4 and increased recruitment of active RNA-pol II to promoters as well as transcribed regions. Altogether, the results described in this thesis reveal a new role for the mTOR kinase in the regulation of gene expression to facilitate the cellular adaptive response upon osmostress. / Las respuestas adaptativas frente al estrés permiten a las células mantener su crecimiento así como su potencial proliferativo. Aunque se ha establecido que el crecimiento y la proliferación celular pueden inhibirse en respuesta a un estrés intenso, en situaciones de estrés tolerable las células pueden mantener su crecimiento y proliferación mediante la inducción de respuestas compensatorias. La quinasa mTOR es una proteína clave para el mantenimiento de la capacidad proliferativa y del crecimiento en las células de mamífero; además se ha descrito que es sensible a varios estreses. Sin embargo, poco se sabe acerca del papel que juega en las respuestas de adaptación que son utilizadas por las células para resistir el estrés y mantener así su capaciad de crecimiento. Nuestro trabajo se ha centrado en el ámbito del estrés osmótico, en cuyo caso las células pueden adaptarse mediante la transcripción de diversos genes especializados. Nuestro estudio demuestra que mTOR se encuentra activo en condiciones moderadas de estrés osmótico y regula la indución de un conjunto de genes mediante mecanismos dependientes e independientes de NFAT5, el principal factor de transcripción responsable de la transcripción de genes en respuesta a un estrés hipertónico. Además, observamos que la mayoría de los genes cuya inducción es sensible a la actividad de mTOR tienen funciones en la regulación del crecimiento y de la proliferación. También hemos identificado a REDD1 y REDD2 como genes que se inducen en respuesta a estrés osmótico dependientes de mTOR, y que con anterioridad se habían caracterizado en otros escenarios de estrés actuando como reguladores negativos de la ruta de señalización de mTORC1. Por último hemos observado que mTOR origina cambios en la cromatina, promoviendo una configuración permisiva para la transcripción, con un incremento de la acetilación de la histona H4 y un aumento en el reclutamiento de la forma activa de la RNA-polimerasa II en los promotores y regiones transcritas de ciertos genes. En resumen, los resultados descritos en esta tesis muestran un nuevo papel de la quinasa mTOR en la regulación de la expresión génica facilitando así la respuesta de adaptación celular frente al estrés osmótico.
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Salt stress in rice : adaptive mechanisms for cytosolic sodium homeostasis /Kader, Md. Abdul, January 2006 (has links) (PDF)
Diss. (sammanfattning) Ultuna : Sveriges lantbruksuniv., 2006. / Härtill 4 uppsatser.
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Estudo da expressão dos genes das bombas de prótons (V-ATPase e V-PPase) e dos contra-transportadores vacuolares (NHX) de Vigna unguiculata (L.) Walp submetidos a estresses abióticos / Expression study of proton pumps(V-ATPase and V-PPase) and vacuolar antiport (NHX) genes from Vigna unguiculata (L.) Walp submitted to abiotic stressSobreira, Alana Cecília de Menezes 12 November 2012 (has links)
SOBREIRA, Alana Cecília de Menezes. Estudo da expressão dos genes das bombas de prótons (V-ATPase e V-PPase) e dos contra-transportadores vacuolares (NHX) de Vigna unguiculata (L.) Walp submetidos a estresses abióticos.2009 f. Dissertação (Mestrado em Bioquímica) - Centro de Ciências, Departamento de Bioquímica e Biologia Molecular, Universidade Federal do Ceará, Fortaleza, 2009. / Submitted by JOANA BEZERRA (joanabib@yahoo.com.br) on 2012-11-09T21:07:31Z
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2009_tese_acmsobreira.pdf: 1938746 bytes, checksum: 064fea08dd8578e2f6b67de140140d86 (MD5) / The acummulation of Na+ in the central vacuole represents an important mechanism for plants to cope with salt stress. The vacuolar content and the regulations of their volumes in vegetable cells depend on the activity of transporters and channels located in the tonoplast (vacuolar membrane). The vacuolar membrane possesses two different proton pumps (V-ATPase and V-PPase), aquoporine, and systems of primary and secondary transporters like the vacuolar Na+/H+ antiporter (NHX). The two transmembrane proton pumps work as systems of primary transport in vegetable cells and both enzymes generate a difference of proton electrochemical potential through the vacuolar membrane which can provide energy to antiport system, H+/substrate. The vacuolar Na+/H+ antiporter, uses the electrochemical gradient generated by the primary transporters to pump Na+ ions inward the vacuole. In the present work were first determined the Na+ and K+ content followed by the gene expression of the vacuolar proton pumps (VHA-A, VHA-E and HVP) and the vacuolar antiporters (NHX2 and NHX6) from seedlings of Vigna unguiculata subjected to salt and osmotic stress. The seedlings were grown on nutritive medium in the absence of NaCl and PEG (control condition), presence of NaCl 100 mM (salt stress) or in the presence of PEG 6000 200,67g.L-1 (osmotic stress). The ion Na+ content essay showed an increase in all plant tissues when submitted to salt stress, while the K+ ions decreased in the same condition. The gene expression of the vacuolar proton pumps and the Na+ antiporter from roots and leaves showed an increase in all studied conditions being more expressive to V-PPase, NHX2 and NHX6 suggesting a coordinated regulation of these genes. The results from leaves showed that VHA-A and VHA-E were increased, while the others genes tend to remain constant in the osmotic stress. These results suggest that salt and osmotic stress induced a differential regulation of all studied genes, being the vacuolar Na+ antiporters an important part on keep the cellular homeostasis when the plants were submitted to salt stress. / O acúmulo de Na+ no vacúolo central representa um importante mecanismo de defesa de plantas contra o estresse salino. A regulação dos volumes e conteúdos dos vacúolos de células vegetais depende da atividade de transportadores e canais localizados no tonoplasto (membrana vacuolar). A membrana vacuolar possui duas distintas bombas de prótons (V-ATPase e V-PPase), aquoporinas e vários sistemas de transportes ativos e/ou secundários, como os contra-transportadores Na+/H+ vacuolares. As duas bombas de prótons transmembranares funcionam como sistemas de transporte primário nas células vegetais e ambas as enzimas geram uma diferença de potencial eletroquímico de prótons através da membrana vacuolar. Os contra-transportadores vacuolares Na+/H+ utilizam o gradiente eletroquímico de prótons gerado pelos transportadores primários para transportar Na+ para dentro do vacúolo. No presente trabalho inicialmente foram determinados os conteúdos de íons Na+ e K+ em raízes, hipocótilos e folhas e em seguida a análise da expressão dos genes das bombas de prótons (VHA-A, VHA-E e HVP) e dos contra-transportadores vacuolares (NHX2 e NHX6) em plântulas de Vigna unguiculata (L.) Walp cv. Vita 5 submetidas a estresse salino e osmótico. As plântulas foram crescidas em meio nutritivo na ausência de NaCl e PEG (controle), na presença de 100 mM de NaCl (estresse salino) ou na presença de 200,67 g/L de PEG (estresse osmótico). O conteúdo de íons Na+ aumentou em todos os tecidos da planta quando submetidos ao estresse salino (NaCl 100 mM) enquanto que o conteúdo de íons K+ diminuiu na mesma condição. A expressão dos genes das bombas de prótons e dos contra-transportadores vacuolares de folhas e de raízes no estresse salino aumentou em todas as condições estudadas, porém o aumento foi mais expressivo para os genes da V-PPase, NHX2 e NHX6 sugerindo uma regulação paralela entre esses genes. Já no estresse osmótico, os resultados para as folhas mostraram que a expressão dos genes VHA-A e VHA-E aumentaram enquanto que os outros genes não sofreram mudanças significativas. Nossos resultados sugerem que o estresse salino e o estresse osmótico induziram uma regulação diferenciada em todos os genes sendo o contra-transportador Na+/H+ importante na homeostase celular quando as plantas foram submetidas ao estresse salino e osmótico.
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Aumento da tolerância de Saccharomyces cerevisiae a fatores estressantes da fermentação etanólica: linhagens modificadas e suplementação de aminoácidos / Increasing Saccharomyces cerevisiae tolerance to stressing factors of ethanolic fermentation: modified strains and amino acid supplementationCamila de Souza Varize 15 January 2018 (has links)
O aumento da participação dos biocombustíveis na matriz energética mundial pode ajudar a prolongar a existência das reservas de petróleo, mitigar as ameaças representadas pela mudança climática e permitir melhor segurança do fornecimento de energia em uma escala global. Neste cenário, o processo brasileiro da produção de etanol a partir da cana-de-açúcar tem ganhado papel de destaque, pelo alto rendimento e baixo custo da produção. Linhagens de S. cerevisiae são amplamente empregadas nas fermentações industriais e, embora sejam consideradas mais tolerantes em relação a outras, o processo brasileiro impõe uma variedade de fatores estressantes sob a mesma, afetando o seu metabolismo e crescimento. A fermentação com alto teor alcoólico, realizada a partir da utilização de mostos contendo altas concentrações de açúcares, é uma das maneiras mais eficientes de se obter elevados níveis de etanol. No entanto, tal tecnologia procede ocasionando efeitos deletérios adicionais à levedura. Neste contexto, aumentar a tolerância da levedura é de fundamental importância para alcançar um desempenho fermentativo satisfatório. Neste estudo foram avaliadas linhagens de S. cerevisiae, isogênicas a linhagem industrial CAT-1, com a sobre-expressão dos genes TRP1 e MSN2, envolvidos na biossíntese de triptofano e na resposta geral ao estresse, respectivamente. Tais linhagens foram avaliadas quanto ao seu potencial para realizar fermentações com alto teor alcoólico, simulando as condições industriais brasileiras. Os resultados revelaram que o gene MSN2, na versão truncada, favoreceu a linhagem principalmente com relação ao estresse osmótico, aumentando a velocidade de fermentação e o consumo de açúcares. O gene TRP1 promoveu maior crescimento da linhagem em meio YEPD com 8% de etanol, contudo, tornou a linhagem menos viável em concentrações acima deste nível. No presente trabalho também foi avaliado o efeito da suplementação de aminoácidos na fisiologia da linhagem CAT-1 em meio YNB e em mostos de melaço e xarope de cana-de-açúcar. A suplementação com histidida promoveu maior crescimento e viabilidade celular nos diferentes meios testados. Além de histidina, os aminoácidos lisina e alanina aumentaram o crescimento da CAT-1 em mosto de melaço. A suplementação de triptofano e asparagina também promoveu aumento da viabilidade celular em mosto de xarope. Por outro lado, nos testes em microplacas a suplementação com cisteína depreciou o crescimento da linhagem em meio YNB com 10 e 12% de etanol e em mosto de melaço com 20% de ART. Os resultados obtidos indicam que tanto a engenharia genética, quanto a suplementação de aminoácidos podem ser alternativas viáveis para aumentar a tolerância de S. cerevisiae, para suportar condições de múltiplo estresse, encontradas em destilarias brasileiras. / The expansion biofuels participation in the world energy matrix would help to extend the existence of fossil fuel reservoirs, mitigate the threats of climate change, and enable a better security of energy supply. The Brazilian process of ethanol production from sugarcane has gained an important role in the global energy scenario, for the high yield and low production cost. S. cerevisiae species is widely used in industrial fermentations for being resistant, but the Brazilian process imposes a variety of stressing factors to the yeast, affecting its metabolism and growth. The Very High Gravity Fermentation is performed by the utilization of musts with high sugar concentration and is one of the most efficient ways for obtaining high ethanol levels. However, this technology causes additional deleterious effects to the yeast. In this context, increasing yeast tolerance is of fundamental importance for a satisfactory fermentative performance. In this study we assessed S. cerevisiae strains - isogenic to the industrial strain CAT-1 - with over expression of TRP1 and MSN2 genes involved to tryptophan biosynthesis and in general stress response, respectively. These strains were evaluated for their potential to perform fermentations with high ethanol content, simulating the conditions of Brazilian distilleries. The results showed that the MSN2 gene in the truncated version improved strain mainly to respond to the osmotic stress, increasing in fermentation velocity and the consumption of sugars. The TRP1 gene overexpression promoted higher growth in YEPD medium with 8% ethanol, however, decreased viability at concentrations above this level. The present work also evaluated the effect of amino acid supplementation on the physiology of the CAT-1 strain in YNB medium and in molasses and syrup of sugarcane. Histidide supplementation increased the growth and cell viability in the different media tested. In addition to histidine, the amino acids lysine and alanine increased the growth of CAT-1 in molasses. Supplementation of tryptophan and asparagine also promoted increased cell viability in sugarcane syrup. On the other hand, in microplate assays, cysteine supplementation decreased growth in YNB medium with 10 and 12% ethanol, and in molasses with 20% ART. The results indicate that both genetic engineering and amino acid supplementation may be viable alternatives to increase tolerance of S. cerevisiae to supporting multiple stress conditions typical in Brazilian distilleries.
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Adaptation de Staphylococcus xylosus à la matrice carnée, impact des composés nitrosés et utilisation des sources de fer / Adaptation of Staphylococcus xylosus to meat model, impact of nitroso compounds and use of iron sourcesVermassen, Aurore 18 December 2014 (has links)
Staphylococcus xylosus est couramment utilisé comme ferment dans les produits carnés pour son rôle dans le développement de la flaveur et de la couleur. Beaucoup de propriétés technologiques ont été caractérisées in vitro. Cependant, les mécanismes moléculaires mis en place par cette bactérie pour s’adapter à une matrice carnée et aux composés nitrosés, fréquemment ajoutés dans ces produits, étaient méconnus. Pour identifier ces mécanismes, des approches de transcriptomique globale ont été mises en œuvre. S. xylosus survit dans un modèle viande en modulant l’expression de 55 % de ses gènes. Il surexprime des gènes codant des protéines impliqués dans le catabolisme du glucose et du gluconate et des gènes codant des peptidases. En parallèle, il sous exprime de nombreux gènes impliqués dans la synthèse des acides aminés probablement en raison de leur disponibilité dans le modèle viande. Le modèle viande est un milieu riche en divers substrats et la bactérie pourrait adapter sa physiologie via les régulateurs transcriptionnels CcpA et CodY. S. xylosus répond au sel ajouté au modèle viande en surexprimant des gènes impliqués dans des mécanismes d’osmoprotection, d’extrusion de Na + et de protons. S. xylosus répond aux composés nitrosés dans le modèle viande en modulant 24 % de son génome. Ces composés nitrosés génèrent un stress nitrosant et S. xylosus répond à ce stress par la surexpression de gènes impliqués dans l’homéostasie du fer via la dérépression du régulateur Fur. S. xylosus surexprime aussi des gènes codant des enzymes antioxydants via la dérépression du régulateur PerR. De plus, il surexprime des gènes impliqués dans la réparation de l’ADN et des protéines. La viande est un aliment riche en fer hémique et non hémique. Ainsi, S. xylosus est capable d’acquérir du fer à partir de ferritine, de transferrine et potentiellement des hémoprotéines. La ferritine est une source préférentielle de fer pour S. xylosus. Un opéron codant potentiellement un complexe membranaire impliqué dans des réactions d’oxydo-réduction a été identifié. Un mutant de délétion/insertion dans le premier gène de l’opéron confirme que ce système pourrait jouer un rôle dans l’acquisition du fer de la ferritine chez S. xylosus. Cette étude révèle un changement global dans l’expression des gènes de S. xylosus dans un modèle viande, elle souligne la capacité de S. xylosus à s’adapter à un stress osmotique ou nitrosant et elle caractérise pour la première fois la capacité d’un staphylocoque à utiliser du fer de la ferritine. / Staphylococcus xylosus is used as starter culture in meat product for its role in the development of flavor and color. S. xylosus is characterized for its technological properties in vitro. However, the molecular mechanisms for its adaptation in meat with or without nitrate and nitrite, frequently added in meat product, remained unknown. Global transcriptomic approaches were carried out to determine the molecular mechanisms. S. xylosus modulated the expression of 55 % of the genes to survive in a meat model. Many genes encoding proteins involved in glucose and gluconate catabolisms and peptidases were up expressed. In parallel, a lot of genes involved in amino acids synthesis were down regulated, probably due to their availability in the meat model. The meat model is a rich medium composed of various substrates and S. xylosus adapted its physiology through the transcriptional regulators CcpA and CodY. Finally, it responded to salt added in the meat model in overexpressing genes involved in mechanisms of osmoprotection, Na + and H + extrusion. S. xylosus modulated the expression of 24 % of the genes in presence of nitroso compounds in the meat model. These compounds generated a nitrosative stress. S. xylosus responded to this stress by over expressing genes involved in iron homeostasis through the derepression of the regulator Fur. It over expressed also genes encoding antioxidant enzymes through the derepression of the regulator PerR. Moreover, it over expressed genes involved in DNA and proteins repairs. Meat is rich in hemic and non-hemic iron. S. xylosus is able to grow in presence of ferritin, transferrin and potentially hemoproteins. Ferritin is one of preferential iron sources. An operon encoding potentially a membranous complex involved in oxydo-reduction reactions has been identified. A strain defective in the first gene of the operon confirmed that this complex could contribute to the iron acquisition from ferritin. This study revealed a global change in the gene expression of S. xylosus in the meat model; it highlighted ability of S. xylosus to mitigate nitrosative or osmotic stress, it characterised for the first time the capacity of a Staphylococcus to acquire ferritin-iron.
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