Global ETD Search

51	Analyse de l'effet de la contamination du sol sur la croissance et la physiologie de 11 cultivars de Salix Grenier, Vanessa 12 1900 (has links) Mon mémoire de maîtrise a été réalisé dans le cadre du projet Génorem (www.genorem.ca), un projet multidisciplinaire qui réunit différents chercheurs de l'Université de Montréal et de l'Université McGill dans le but d'améliorer les techniques utilisées en bioremédiation. Dans le cadre de l'étude, des saules à croissance rapide (Salix sp.) ont été utilisés comme plantes modèles dans l'étude. Ainsi, 11 cultivars de saule ont été suivis afin de déterminer leur potentiel à produire un bon rendement de biomasse, à tolérer des conditions de stress sévère causé par la présence de HAPs (hydrocarbures aromatiques polycycliques) , BPCs (biphényles polychlorés) et d'hydrocarbures pétroliers C10-C50. L'expérimentation consistait en une plantation de saule à forte densité qui a été mise en place en 2011 sur le site d'une ancienne industrie de pétrochimie à Varennes, dans le sud du Québec. Les boutures des génotypes sélectionnés ont été plantées sur une superficie d'environ 5000 m2. Les plantes ont été suivies pendant les deux saisons de croissance suivant le recépage et une série de paramètres de croissance et de mesures physiologiques ont été récoltés (surface foliaire, taux de chlorophylle, conductance stomatique et statut nutritionnel) dans le but d'évaluer et de comparer les performances de chaque génotype sur un sol pollué. Les analyses statistiques ont démontré que le cultivar S. miyabeana (SX61) était le meilleur producteur de biomasse sur le site contaminé, tandis que S. nigra (S05) et S. acutifolia (S54) présentaient la meilleure capacité photosynthétique. S. dasyclados (SV1), S. purpurea (‘Fish Creek’) et S. caprea (S365) ont semblé particulièrement affectés par la présence de contaminants. La capacité d'établissement et la croissance de S. nigra (S05), S. eriocephala (S25) and S. purpurea x S. miyabeana (‘Millbrook’) indiquent une tolérance globale supérieure à la pollution . Cette analyse comparative des différentes réponses physiologiques des saules cultivés sur un sol contaminé pourra guider le processus de sélection de plantes et les techniques de bioremédiation dans les futurs projets de phytoremédiation. / My master thesis is part of a larger multidisciplinary initiative called GenoRem (www.genorem.ca). GenoRem brings together scientists from Université de Montréal and McGill University in a quest to improve bioremediation techniques through molecular and biological processes. Eleven fast-growing willow (Salix sp.) cultivars were studied, primarily to identify those that produce high biomass yields, demonstrate capacity to thrive under harsh environmental conditions and to tolerate the presence of PAHs (polycyclic aromatic hydrocarbons), PCBs (polychlorinated biphenyls) and C10-C50. A high-density field experiment was undertaken during the summer of 2011 on a former petrochemical industrial site in southern Québec, Canada. Cuttings of selected willow genotypes were planted on an area covering ~5000 m². Plants were monitored over the two growing seasons that followed the coppicing by recording a series of growth parameters and physiological measurements (specific leaf area, chlorophyll concentration, stomatal conductance and nutrient concentration) in order to compare growth performance of each genotype on contaminated soils. S. miyabeana cultivars (SX61) achieved the highest biomass production, while S. nigra (S05) and S. acutifolia (S54) had the highest photosynthetic capacity. S. dasyclados (SV1), S. purpurea (‘Fish Creek’) and S. caprea (S365) were negatively affected by the presence of contaminants The establishment capacity and development of S. nigra (S05), S. eriochephala (S25) and S. purpurea X S. miyabeana (‘Millbrook’) were globally less influenced by soil pollution. This comparative analysis of physiological responses of willow on contaminated soil will guide plant selection processes and bioremediation practices in future phytoremediation projects. Salix écophysiologie végétale phytoremédiation composés organiques sol Salix physiology phytoremediation organic compounds soil
52	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
53	Effets de facteurs pédoclimatiques sur la composition et l’anatomie du bois de cinq cultivars de saule destinés aux biocarburants Berthod, Nicolas 02 1900 (has links) En 2011, cinq (5) cultivars de saules ont été sélectionnés pour leur rendement en biomasse. Ils ont été plantés sur quatre sites de la province du Québec et ont été maintenus selon le protocole de la culture intensive sur courtes rotations (CICR) afin de déterminer leur potentiel pour la bioénergie dans des environnements contrastés. La composition et l’anatomie du bois de ces cultivars ont été caractérisées et comparés en fonction des conditions environnementales caractéristiques de chaque site. La hauteur et le diamètre à la base des plantes diffèrent selon les sites. Ainsi, les cultivars répondent de façon spécifique aux conditions pédoclimatiques dans lesquelles ils sont cultivés. L’effet de l’environnement n’a pas été mis en évidence sur la teneur en lignine des cultivars. Cependant, un effet génotypique a pu être constaté soulignant l’importance de la sélectivité des cultivars. La densité du bois a étonnamment conservé la même hiérarchie génotypique entre les sites. À l’opposé, l’anatomie du bois présente des différences notamment au niveau des caractéristiques des fibres et des vaisseaux. Une forte teneur en polyphénols ainsi que des fibres moins larges et des vaisseaux plus nombreux ont été observés sur le site dont le bois est le plus dense supposant l’effet probable d’un stress abiotique. De plus, deux fois plus de fibres gélatineuses, fibres riches en cellulose, ont été identifiées sur ce site montrant un intérêt pour la production de bioéthanol. / In 2011, five (5) willow cultivars were selected for biomass yield. They were planted according to SRC (Short Rotation Coppice) protocol on four sites in Quebec (Canada) to determine their bioenergy potential in contrasting environments. Wood composition and anatomical traits were characterized and compared between both genotypes and environmental growing conditions. Tree height and stem diameter differed between sites, and pedoclimatic conditions more favorable for willow growth were identified. However, each cultivar showed a specific response to its environment. While no significant variation in lignin content was observed between sites, a clonal effect confirms the importance of cultivar selection. Surprisingly, the pattern of genotype variability in stem density was the same on all sites. Wood anatomy differed on fiber and vessel traits between high and low wood density sites, which suggests a probable effect of an abiotic stress. Furthermore, twice as many cellulose-rich G fibers were also found at the most dense site, evidence of potential for use in bioethanol production. CICR Biocarburant Densité Anatomie du bois Bois de tension SRCW Biofuel Density Wood anatomy Tension wood
54	Accumulation et translocation de cinq éléments traces dans la biomasse aérienne de végétaux d’intérêt dans un contexte de phytoremédiation Lapierre, Esther 05 1900 (has links) No description available. verdissement phytoremédiation translocation éléments traces technosol cuivre zinc argent sélénium cadmium greening phytoremediation trace element copper zinc selenium silver
55	Physiology of Potassium Nutrition in Cereals: Fluxes, Compartmentation, and Ionic Interactions Szczerba, Mark 01 August 2008 (has links) Potassium (K+) is an essential nutrient and the most abundant cation in plant cells. Plants possess two transport systems for K+ acquisition: a high-affinity system (HATS), operating at external K+ concentrations ([K+]ext) below 1 mM, and showing reduced transport activity in the presence of ammonium (NH4+); and, a low-affinity system (LATS), operating at [K+]ext above 1 mM, that is not affected by NH4+. K+ transport and compartmentation were investigated in barley (Hordeum vulgare L.) and rice (Oryza sativa L.) using the non-invasive technique of compartmental analysis by tracer efflux (CATE), to simultaneously determine unidirectional membrane fluxes, ion concentrations, and exchange characteristics in subcellular compartments. These studies revealed striking differences in unidirectional K+ fluxes between HATS and LATS. It was found that flux measurements, using traditional direct influx (DI) protocols, accurately represented HATS influx, but underestimated LATS influx by as much as seven-fold. In both barley and rice, LATS K+ fluxes were found to undergo rapid, futile cycling, with the ratio of efflux:influx 3 to 5 times greater, and the cytosolic exchange rate 2 to 3 times faster than under HATS. Based upon plasma-membrane electrical potential measurements, efflux was found to be active under LATS conditions. LATS-mediated conditions for K+ were found to provide relief from NH4+ toxicity in barley by immediately reducing NH4+ influx by more than 50%, and significantly reducing NH4+ futile cycling. Employing the K+ channel inhibitors cesium, lanthanum, and tetraethylammonium, NH4+ was shown to have both K+-sensitive and –insensitive influx pathways at high [NH4+]ext. Based on current models of flux energetics, the combined uptake of K+ and NH4+ was found to utilize 60% of root oxygen consumption. Barley and rice both showed signs of NH4+ toxicity at low [K+]ext, but rice recovered at much lower [K+]ext, suggesting a crucial role of K+ in the NH4+-tolerance of rice. These experiments address fundamental aspects of K+ fluxes, and help provide a physiological framework for future studies of K+ transport and mineral nutrition. Potassium Compartmental analysis Nitrogen Plant physiology Efflux Influx Electrophysiology Barley Rice Ammonium Nitrate Cellular Ion Exchange Low-affinity transport system High-affinity transport system 0817
56	Physiology of Potassium Nutrition in Cereals: Fluxes, Compartmentation, and Ionic Interactions Szczerba, Mark 01 August 2008 (has links) Potassium (K+) is an essential nutrient and the most abundant cation in plant cells. Plants possess two transport systems for K+ acquisition: a high-affinity system (HATS), operating at external K+ concentrations ([K+]ext) below 1 mM, and showing reduced transport activity in the presence of ammonium (NH4+); and, a low-affinity system (LATS), operating at [K+]ext above 1 mM, that is not affected by NH4+. K+ transport and compartmentation were investigated in barley (Hordeum vulgare L.) and rice (Oryza sativa L.) using the non-invasive technique of compartmental analysis by tracer efflux (CATE), to simultaneously determine unidirectional membrane fluxes, ion concentrations, and exchange characteristics in subcellular compartments. These studies revealed striking differences in unidirectional K+ fluxes between HATS and LATS. It was found that flux measurements, using traditional direct influx (DI) protocols, accurately represented HATS influx, but underestimated LATS influx by as much as seven-fold. In both barley and rice, LATS K+ fluxes were found to undergo rapid, futile cycling, with the ratio of efflux:influx 3 to 5 times greater, and the cytosolic exchange rate 2 to 3 times faster than under HATS. Based upon plasma-membrane electrical potential measurements, efflux was found to be active under LATS conditions. LATS-mediated conditions for K+ were found to provide relief from NH4+ toxicity in barley by immediately reducing NH4+ influx by more than 50%, and significantly reducing NH4+ futile cycling. Employing the K+ channel inhibitors cesium, lanthanum, and tetraethylammonium, NH4+ was shown to have both K+-sensitive and –insensitive influx pathways at high [NH4+]ext. Based on current models of flux energetics, the combined uptake of K+ and NH4+ was found to utilize 60% of root oxygen consumption. Barley and rice both showed signs of NH4+ toxicity at low [K+]ext, but rice recovered at much lower [K+]ext, suggesting a crucial role of K+ in the NH4+-tolerance of rice. These experiments address fundamental aspects of K+ fluxes, and help provide a physiological framework for future studies of K+ transport and mineral nutrition. Potassium Compartmental analysis Nitrogen Plant physiology Efflux Influx Electrophysiology Barley Rice Ammonium Nitrate Cellular Ion Exchange Low-affinity transport system High-affinity transport system 0817
57	Examining the Regulation of 3-Deoxy-D-arabino-heptulosonate 7-phosphate Synthase in the Arabidopsis thaliana shikimate Pathway Johnson, Daniel 09 January 2014 (has links) 3-Deoxy-D-arabino-heptulosonate 7-phosphate (DAHP) synthase (DHS) catalyzes the first step of the shikimate pathway - a pathway involved in Tyrosine (Tyr), Tryptophan (Trp) and Phenylalanine (Phe) biosynthesis - by condensation of phosphoenolpyruvate and erythrose-4-phosphate to DAHP. Our lab previously demonstrated that Arabidopsis thaliana shikimate pathway flux is regulated by Tyr and Trp. This project suggests that A. thaliana DHS1 overexpressor lines have increased Trp accumulation with Tyr treatment, and that an A. thaliana DHS2 overexpressor line treated with Tyr has unchanged Trp accumulation, indicating that AtDHS2 is Tyr-sensitive. Confocal microscopy of all 3 AtDHS isoforms fused to yellow fluorescent protein demonstrates chloroplast localization. Bimolecular fluorescence complementation indicates that protein-protein interactions occur in the cytoplasm, and not in the chloroplast, for AtDHS1 and AtDHS2 with the metabolic regulator At14-3-3ω. These findings suggest that protein-protein interactions could regulate accumulation of AtDHS2 in the chloroplast, and are perhaps modulated by Tyr. BiFC shikimate pathway tryptophan tyrosine confocal regulation protein-protein interaction dahp synthase 14-3-3 phosphorylation Arabidopsis thaliana yfp 0309 0379 0817 0307
58	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
59	Organogenesis in Vitro under Altered Auxin Signaling Conditions Smirnova, Tatiana 27 November 2013 (has links) The ratio of auxin to cytokinin determines de novo organogenesis in plants. Relatively little is known about the effect of genetically altered auxin signaling on in vitro organogenesis. Here, callusogenesis, shoot, and root formation were studied in loss- (LOF) and gain-of-function (GOF) alleles in two phylogenetically related Auxin Response Factors (ARFs), MONOPTEROS (MP/ARF5) and NON-PHOTOTROPHIC HYPOCOTYL 4 (NPH4/ARF7). Reduced MP activity greatly diminished shoot regeneration, and partially diminished callusogenesis and root formation. LOF in NPH4 strongly decreased callusogenesis, and mildly decreased shoot and root regeneration in particular categories of explants. By contrast, organogenesis responses were strongly increased in aerial explants carrying the GOF transgene dMP. Thus, both MP and NPH4 seem to act as positive regulators of certain organogenesis processes and the GOF dMP transgene may be of interest for stimulating organogenesis in plant species with poor regeneration properties. Also, organogenesis in vitro may reveal unknown developmental ARF functions. auxin signaling auxin cytokinin auxin response factors (ARFs) callus de novo organogenesis shoot regeneration MONOPTEROS (MP/ARF5) NON-PHOTOTROPHIC HYPOCOTYL4 (NPH4/ARF7) Arabidopsis thaliana 0379 0369 0307 0817 0309
60	Organogenesis in Vitro under Altered Auxin Signaling Conditions Smirnova, Tatiana 27 November 2013 (has links) The ratio of auxin to cytokinin determines de novo organogenesis in plants. Relatively little is known about the effect of genetically altered auxin signaling on in vitro organogenesis. Here, callusogenesis, shoot, and root formation were studied in loss- (LOF) and gain-of-function (GOF) alleles in two phylogenetically related Auxin Response Factors (ARFs), MONOPTEROS (MP/ARF5) and NON-PHOTOTROPHIC HYPOCOTYL 4 (NPH4/ARF7). Reduced MP activity greatly diminished shoot regeneration, and partially diminished callusogenesis and root formation. LOF in NPH4 strongly decreased callusogenesis, and mildly decreased shoot and root regeneration in particular categories of explants. By contrast, organogenesis responses were strongly increased in aerial explants carrying the GOF transgene dMP. Thus, both MP and NPH4 seem to act as positive regulators of certain organogenesis processes and the GOF dMP transgene may be of interest for stimulating organogenesis in plant species with poor regeneration properties. Also, organogenesis in vitro may reveal unknown developmental ARF functions. auxin signaling auxin cytokinin auxin response factors (ARFs) callus de novo organogenesis shoot regeneration MONOPTEROS (MP/ARF5) NON-PHOTOTROPHIC HYPOCOTYL4 (NPH4/ARF7) Arabidopsis thaliana 0379 0369 0307 0817 0309

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