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The Transcriptional Regulation of the Central Plant Defense Signal, Salicylic AcidZheng, Xiao-yu January 2014 (has links)
<p>Salicylic acid (SA) is a central plant defense signal. It is not only required for closing the stomata upon infection to prevent pathogens from entering into the plant apoplast, but also mediates defense responses activated by pathogen-originated microbe-associated molecular patterns (MAMPs) and effectors in the infected tissues. In addition, SA is a necessary and sufficient signal for systemic acquired resistance (SAR). In <italic>Arabidopsis</italic> <italic>thaliana</italic>, SA level increases in response to pathogen attack, which is essential for activating defense responses. This SA accumulation involves transcriptional activation of several genes including <italic>ICS1</italic> (<italic>ISOCHORISMATE</italic> <italic>SYNTHASE</italic> <italic>1</italic>), <italic>EDS5</italic> (<italic>ENHANCED</italic> <italic>DISEASE</italic> <italic>SUSCEPTIBILITY</italic> <italic>5</italic>), <italic>EDS1</italic> (<italic>ENHANCED</italic> <italic>DISEASE</italic> <italic>SUSCEPTIBILITY</italic> <italic>1</italic>), <italic>PAD4</italic> (<italic>PHYTOALEXIN-DEFICIENT</italic> <italic>4</italic>) and <italic>PBS3</italic> (<italic>avrPphB</italic> <italic>SUSCEPTIBLE</italic> <italic>3</italic>). However, it is not well understood how pathogenic signals induce these SA accumulation genes. Interestingly, our time-course transcriptome analysis showed that these five genes share a similar pathogen-induced expression pattern, suggesting the existence of common transcription factors (TFs). Through yeast-one-hybrid screening, a TF NTL9 was identified for its interactions with the promoters of the SA accumulation genes. Preferentially expressed in guard cells, NTL9 activates the expression of SA accumulation genes in guard cells. The <italic>ntl9</italic> mutant is defective in pathogen-induced stomatal closure mediated by a well-characterized MAMP, flg22. Consistent with the stomatal closure defect, the <italic>ntl9</italic> mutant exhibits elevated susceptibility to surface-inoculated pathogens. The stomatal closure defect of the <italic>ntl9</italic> mutant can be rescued by exogenous application of SA, demonstrating that NTL9 acts upstream of SA in stomatal closure response. These results suggest that NTL9-mediated activation of SA accumulation genes is essential for MAMP-triggered stomatal closure.</p><p>While plants induce SA to activate defense responses, pathogens can also produce virulence factors to counteract the effects of SA. Coronatine is one such virulence factor produced by <italic>Pseudomonas</italic> <italic>syringae</italic>. Coronatine is known to promote opening of stomata for bacterial entry, bacterial growth in the apoplast, systemic susceptibility and development of disease symptoms such as chlorosis. In the process of examining the mechanisms underlying coronatine-mediated virulence, three homologous TFs, ANAC019, ANAC055 and ANAC072, were found to be activated by coronatine directly through the TF, MYC2. Genetic characterization of these three TF mutants revealed that these TFs mediate multiple virulence effects of coronatine by inhibiting SA accumulation. To exert this inhibitory effect, these TFs repress <italic>ICS1</italic> and activate <italic>BSMT1</italic>, genes involved in SA biosynthesis and inactivation modification, respectively. Thus, a signaling cascade downstream of coronatine was illustrated to dampen SA-mediated defense responses through differential transcriptional regulation of genes related to SA level.</p><p>Taken together, my dissertation studies revealed novel transcriptional regulation of SA production and demonstrated that this transcriptional regulation is a vital point not only for plant defense activation but also for pathogen manipulation to counteract defense responses. Further studies on the interplay of this transcriptional regulation by different TFs would broaden our understanding about the dynamics of plant-pathogen interaction.</p> / Dissertation
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Synthèse asymétrique des acides aminés cyclopropanes et application à la synthèse de la coronatineMoreau, Benoît January 2006 (has links)
Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.
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Nouvelles synthèses de bicycles fonctionnalisésWasnaire, Pierre 25 August 2006 (has links)
De nombreux produits naturels renferment dans leurs structures une ou plusieurs sous-unités bicycliques. Parmi celles-ci, les hydrindanes et les décalines occupent une position privilégiée. Afin d’accéder à ces composés, deux approches originales ont été développées. Elles se basent sur un couplage de Morita-Baylis-Hillman, suivi d’une cyclisation réductrice ou d’une réaction de Stetter intramoléculaire. Outre la synthèse rapide et efficace d’hydrindanones et de décalones substituées, ces séquences réactionnelles ont permis la création d’une large variété d’ènediones bicycliques. L’intérêt de ces méthodologies a pu être illustré lors de la synthèse d’une phytotoxine, l’acide coronafacique. / A large variety of natural products contain, embedded in their architectural framework, one or more bicyclic subunits. Among them, hydrindanes and decalins occupy a cardinal position. As novel approaches towards these substructures, we have developed original sequences based upon two key steps: a Morita-Baylis-Hillman condensation, followed by a reductive cyclisation or an intramolecular Stetter reaction. Having delineated suitable conditions, a rapid and connective synthesis of substituted hydrindanones and decalones can thus be accomplished. The strength of our methodologies was also exemplified by the formation of various bicyclic enediones and their application in the synthesis of coronafacic acid, a phytotoxin.
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A molecular approach to taxol biosynthesisOnrubia Ibáñez, Miriam 03 April 2012 (has links)
Secondary metabolism in plants produces numerous compounds with wide-ranging activities, including the antineoplastic compound taxol and related taxanes. The biotechnological production of taxol has so far been based on empirical studies. The aim of the present work has been to study how the factors that enhance taxane production affect the metabolic profiles and gene expression in productive cells. As a consequence of this work, new potential candidates have been obtained for unknown taxane biosynthetic genes, some bottle-neck steps of taxane biosynthesis (in vitro and in silico) have been identified and a master regulator, not only for taxane biosynthesis, but also for other secondary metabolism routes, has been characterized. Coronatine, a powerful and less harmful elicitor than methyl jasmonate, has been successfully assayed and found to increase taxane production. In the different studies of this work, the expression level of genes that participate in taxol biosynthesis has been determined, clarifying their involvement in the production of this anti-cancer agent. / El metabolismo secundario de las plantas produce numerosos compuestos con un amplio rango de actividades, entre los que se encuentra el compuesto antineoplásico taxol y los taxanos relacionados, la producción biotecnológica del cual se basa en estudios empíricos. El objetivo de este trabajo ha sido estudiar como los factores que incrementan la producción de taxanos afectan los perfiles metabólicos y la expresión génica en los cultivos. De esta manera se han identificado nuevos genes candidatos que codifican para los genes desconocidos de la biosíntesis, algunos pasos limitantes de ésta y se ha caracterizado un regulador relacionado con el metabolismo secundario. Se ha ensayado la coronatina, un elicitor más eficiente para mejorar la producción de taxanos y menos dañino que el jasmonato de metilo. En los diferentes ensayos de este trabajo han sido determinados los niveles de expresión de genes que participan en la biosíntesis de taxol, ayudando a comprender su papel en la producción de este anticancerígeno.
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