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Metabolism of phytoalexins and analogs, and inhibitors of brassinin detoxification in Leptosphaeria maculans2012 April 1900 (has links)
Detoxification of canola chemical defenses (phytoalexins and others) is an important mechanism used by the blackleg fungus Leptosphaeria maculans/Phoma lingam to overcome the plant’s natural defenses. Phytoalexins are anti-microbial defense metabolites produced de novo by plants in response to pathogen attack and other forms of stress. L. maculans is successful in detoxifying several cruciferous phytoalexins into different products. For example, brassinin, a key phytoalexin from crucifers, is transformed into indole-3-carboxaldehyde. This thesis includes investigation of phytoalexin metabolism by L. maculans and related work: (i) transformation pathways of cruciferous phytoalexins and analogues; (ii) design and synthesis of potential inhibitors of brassinin detoxification.
In continuation of previous work, homologues, analogues and structural relatives of brassinin were analysed for metabolism by L. maculans. Products of metabolism of these compounds were identified and the overall metabolic pathways were established. It was concluded that structural relatives of brassinin metabolized differently from brassinin. Antifungal bioassays of the products suggested that all these transformations were detoxification reactions. Among the phytoalexins, rapalexin A was not metabolized whereas, erucalexin was metabolized. Results of these metabolism studies using L. maculans along with the syntheses and antifungal activities of the metabolites will be presented.
In the second part of thesis, inhibition of the detoxification of brassinin by L. maculans using quinolines and isoquinolines was investigated. These compounds resulted from replacement of indolyl containing structures with quinoline and isoquinoline moieties, and various substitutions such as phenyl, thiazolyl, bromo, chloro, hydroxy and methoxy groups. All these compounds were tested for their effect on brassinin detoxification and antifungal activity. Overall, a significant effect on the rate of brassinin detoxification in cultures of L. maculans was detected in the presence of compounds 6-bromo-2-phenylquinoline, 2-phenylquinoline, 3-phenylquinoline, 1-thiazolylisoquinoline. 6-Bromo-2-phenylquinoline was the most effective compound in slowing down the metabolism of brassinin and also was a weak inhibitor of the growth of L. maculans (virulent on canola). Results of the syntheses and evaluation of the compounds are discussed.
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Synthesis of Resveratrol Ester DerivativesRessler, Daniel 01 December 2013 (has links) (PDF)
The goal of this research project was to synthesize derivatives of transresveratrol. In order for resveratrol to be activated and used by the body it needs to bind to Human Serum Albumin (HSA), a protein in blood plasma. The derivatives were synthesized to improve the ability of resveratrol to enter cells as well as improve their ability to bind to HSA. The three derivatives that were synthesized have converted one of the hydroxyl groups on resveratrol to an ether with a methylene chain terminated by a carboxylic acid. By varying the lengths of the methylene chain we varied the water solubility of the resveratrol derivative. This brought the research closer to the goal of determining how this would affect the binding ability to HSA. Currently three derivatives have been synthesized and purified once by column chromatography.
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Biotransformations of fungal phytotoxins in plants and indolyl-3-acetaldoxime in fungi2013 April 1900 (has links)
In the first part of this thesis the metabolism of the phytotoxins destruxin B and sirodesmin PL in crucifers and non-crucifers was studied using HPLC-ESI-MSn. Destruxin B and sirodesmin PL are phytotoxins produced by the phytopathogenic fungi Alternaria brassicae (Berk.) Sacc. (causative agent of blackspot disease) and Leptosphaeria maculans (Desm) Ces. et de Not.[asexual stage Phoma lingam (Tode ex Fr) Desm.] (causative agent of blackleg disease). Five cruciferous species were used in this study: Arabidopsis thaliana L., Brassica rapa L., B. napus L., Thellungiella salsuginea Pallas and Erucastrum gallicum O.E. Schulz. In addition, the cereals Avena sativa L. and Triticum aestivum L. were studied similarly. Destruxin B was metabolized by all crucifers to hydroxydestruxin B, a transformation similar to previously reported reactions in other crucifers. In addition, destruxin B elicited production of phytoalexins in A. thaliana, T. salsuginea and E. gallicum, while no phytoalexins were detected in case of B. rapa and B. napus. In cereals destruxin B was transformed differently. Several metabolites were detected and identified by HPLC-ESI-MSn analyses: hydroxydestruxin B, two isomers of dehydrodestruxin B and desmethyldestruxin B. On the other hand, no metabolites related to transformation of sirodesmin PL were detected in crucifers; however, in cereals sirodesmin PL was transformed to deacetylsirodesmin PL. In all crucifers sirodesmin PL was found to be a stronger elicitor of phytoalexin production than destruxin B.
In the second part of this thesis, mycelia from different pathogenic fungi were screened for indolyl-3-acetaldoxime dehydratase. L. maculans isolate Laird 2 was chosen for isolation, characterization and substrate specificity of aldoxime dehydratase, as it showed the highest specific activity among the tested pathogens. The enzyme was partially purified using three chromatographic steps. It showed Michaelis–Menten kinetics and an apparent molecular mass of about 40 kDa. Based on its substrate specificity, the enzyme appears to be an indolyl-3-acetaldoxime dehydratase
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(+)-Pisatin Biosynthesis: From (-) Enantiomeric Intermediates via an Achiral IsoflaveneCeloy, Rhodesia Mateo January 2013 (has links)
Pterocarpan phytoalexins are antimicrobial compounds produced by legumes when challenged by biotic stresses. Most legumes produce pterocarpan phytoalexins with (-)-stereochemistry but pea (Pisum sativum L.) produces as its major phytoalexin (+)-pisatin. Pea also occasionally produces a minor amount of (-)-maackiain as a pterocarpan phytoalexin, and studies on the biosyntheses of (+)-pisatin and (-)-maackiain have shown that up to (-)-7,2'-dihydroxy-4',5'-methylenedioxyisoflavanone [(-)-sophorol] and 7,2'-dihydroxy-4',5'-methyl-enedioxyisoflavanol [(-)-DMDI]they have common intermediates with (-)-DMDI being where the two pathways diverge. The final step in (+)-pisatin biosynthesis is the methylation of (+)-6a-hydroxymaackiain [(+)-6a-HMK] by 6a-hydroxymaackiain methyltransferase (HMM2) but the steps from (-)-DMDI to (+)-6a-HMK are unknown.The shifting of the stereochemistry from (-)-DMDI to (+)-6a-HMK has been proposed to involve the achiral isoflavene, 7, 2'-dihydroxy-4', 5'-methylene-dioxyisoflav-3-ene (DMDIF). In this dissertation, I have shown that cis-(-)-DMDI is the enzymatic product of (-)-sophorol, and is the precursor of DMDIF which is produced by the dehydration activity of "isoflavene synthase" (IFVS). IFVS activity was not observed in elicited tissues of alfalfa, chickpea, beans, pepper, and broccoli, plants that do not produce (+) pterocarpans. Partial purification of IFVS demonstrated that it is either large in size or tightly complexed with other proteins. The SDS-PAGE of the 29-fold purified product revealed 12 major bands that aggregated into 3 bands in the non-denaturing PAGE. IFVS activity was in band 3 which co-migrated with marker proteins of>100 kDa in size. Proteins identified from LC-MS/MS peptide sequences of the proteins in band 3, when compared to three protein databases, did not identify any proteins with an enzymatic activity expected for IFVS. A disease resistance-response protein (a dirigent-like protein) and two protein-binding proteins were the most abundantly detected proteins in the pea transcriptome-translated database. Also, four of the known enzymes (isoflavone reductase, HMM1, HMM2, and sophorol reductase) involved in (+)-pisatin biosynthesis were among the proteins identified. It may be that IFVS is associated with these other proteins as a complex in vitro and in vivo. The lack of detection of IFVS in the databases could be because it has not yet been sequenced as it functions in a rare biosynthetic pathway.
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ORIGINS OF ISOPRENOID DIVERSITY: A STUDY OF STRUCTURE-FUNCTION RELATIONSHIPS IN SESQUITERPENE SYNTHASESGreenhagen, Bryan T. 01 January 2003 (has links)
Plant sesquiterpene synthases catalyze the conversion of the linear substrate farnesyl diphosphate, FPP, into a remarkable array of secondary metabolites. These secondary metabolites in turn mediate a number of important interactions between plants and their environment, such as plant-plant, plant-insect and plant-pathogen interactions. Given the relative biological importance of sesquiterpenes and their use in numerous practical applications, the current thesis was directed towards developing a better understanding of the mechanisms employed by sesquiterpene synthases in the biosynthesis of such a diverse class of compounds. Substrate preference for sesquiterpene synthases initially isolated from Nicotiana tabacum (TEAS), Hyoscyamus muticus (HPS) and Artemisia annuna (ADS) were optimized with regards to a divalent metal ion requirement. Surprisingly, careful titration with manganese stimulated bona fide synthase activity with the native 15-carbon substrate farnesyl diphopshate (FPP) as well as with the 10-carbon substrate geranyl diphosphate (GPP). Reaction product analysis suggested that the GPP could be used to investigate early steps in the catalytic cascade of these enzymes. To investigate how structural features of the sesquiterpene synthases translate into enzymatic traits, a series of substrate and active site residue contacts maps were developed and used in a comparative approach to identify residues that might direct product specificity. The role and contribution of several of these residues to catalysis and product specificity were subsequently tested by the creation of site-directed mutants. One series of mutants was demonstrated to change the reaction product to a novel sesquiterpene, 4-epi-eremophilene, and while another series successfully transmutated TEAS into a HPS-like enzyme. This is the first report of a rational redesign of product specificity for any terpene synthase. The contact map provides a basis for the prediction of specific configurations of amino acids that might be necessary for as yet uncharacterized sesquiterpene synthases from natural sources. This prediction was tested by the subsequent isolation and validation that valencene synthase, a synthase from citrus, did indeed have the amino acid configuration as predicted. Lastly, an in vitro system was developed for analyzing the interaction between sesquiterpene synthases and the corresponding terpene hydroxylase. Development of this in vitro system is presented as a new important tool in further defining those biochemical features giving rise to the biological diversity of sesquiterpenes.
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Elucidation of the plant immune system by using the elicitor peptide PIP-1 as a chemical probe / エリシターペプチドPIP-1を化学プローブとした植物免疫機構の解明Kim, Yonghyun 23 March 2015 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第19035号 / 農博第2113号 / 新制||農||1031(附属図書館) / 学位論文||H27||N4917(農学部図書室) / 31986 / 京都大学大学院農学研究科応用生命科学専攻 / (主査)教授 宮川 恒, 教授 西田 律夫, 教授 間藤 徹 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM
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Synthesis of Ester Derivatives of Resveratrol as Potential Anti-Cancer DrugsPageni, Parasmani 01 August 2013 (has links) (PDF)
Resveratrol is a naturally occurring phytoalexin of the stilbene family produced by various plants in response to stress, UV radiation, and fungal attack. It is primarily found in peanuts, berries, grape skin, and red wine. Resveratrol has been found to exhibit anti-cancer, anti-inflammatory, anti-aging, and anti-oxidant properties. Research indicates that diets enriched with resveratrol containing substances result in less incidence of cancer. Unfortunately, the low bioavailability and solubility has been a huge setback for its potential prospects. As a result, efforts have been made to synthesize derivatives of resveratrol with increased solubility and bioavailability. Three triester novel resveratrol derivatives 3, 4’, 5-tri (benzoyloxy) stilbene, 3, 4’, 5-tri (toluyloxy) stilbene and 3, 4’, 5-tri (2”-butenoyloxy) stilbene have been synthesized by esterification process that can further be subjected for biological evaluation. Structures and purities of all newly synthesized derivatives were confirmed by 1H, 13C NMR spectroscopy and infrared spectroscopy.
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Phytoalexins from crucifers : probing detoxification pathways in <i>Sclerotinia sclerotiorum</i>Hossain, Mohammad 10 April 2007
This thesis investigates two aspects of phytoalexin metabolism by the phytopathogenic fungus <i>Sclerotinia sclerotiorum</i> (Lib) de Bary: (i) determination of detoxification pathways of structurally different molecules; (ii) design and synthesis of potential inhibitors of enzyme(s) involved in detoxification steps.<p>First, the transformations of important cruciferous phytoalexins by the economically important stem rot fungus, <i>S. sclerotiorum</i>, were investigated. During these studies a number of new metabolic products were isolated, their chemical structures were determined using spectroscopic techniques, and further confirmed by synthesis. The metabolic products did not show detectable antifungal activity against <i>S. sclerotiorum </i> which indicated that these metabolic transformations were detoxification processes. Overall, the results of these transformations suggested that <i>S. sclerotiorum</i> produces various enzymes that can detoxify cruciferous phytoalexins via different pathways. While the detoxifications of strongly and moderately antifungal phytoalexins such as brassilexin, sinalexin, and 1-methoxybrassinin were fast and led to glucosylated products, the transformations of the weakly antifungal phytoalexins brassicanal A, spirobrassinin and 1-methoxyspirobrassinin were very slow and yielded non-glucosylated compounds.<p>Next, the design of potentially selective inhibitors of the brassinin detoxification enzyme, BGT, was sought. Two sets of potential inhibitors of BGT were designed: (i) a group was based on the structure of brassinin, where the indole ring of brassinin was replaced with benzofuran, thianaphthene, 7-azaindole and pyrazolo[1,5-a]pyridine and/or the position of side chain was changed from C-3 to C-2; and (ii) another group based on the structure of camalexin where the thiazole ring of camalexin was replaced with a phenyl group. The syntheses and chemical characterization of these potential detoxification inhibitors, along with their antifungal activity, as well as screening using fungal cultures and cell-free extracts of <i>S. sclerotiorum</i>, were examined. The results of these screening indicated that 3-phenylindoles, 3-phenylbenzofuran, 5-fluorocamalexin, methyl (indol-2-yl)methyl-dithiocarbamate, methyl (benzofuran-3-yl)methyldithiocarbamate and methyl (benzo-furan-2-yl)methyldithiocarbamate could slow down the rate of detoxification of brassinin in fungal cultures and also in cell-free extracts of <i>S. sclerotiorum</i>. Among the designed compounds, 3-phenylindole appeared to be the best inhibitor both in fungal cultures and in cell-free extracts. Metabolism studies of all the designed compounds using fungal cultures of <i>S. sclerotiorum</i> indicated that they were metabolized by <i>S. sclerotiorum</i> to glucosyl derivatives, although at much slower rates.<p>It is concluded that some inhibitors that can slow down the rate of metabolism of brassinin could be good leading structures to design more active inhibitors of BGT.
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Phytoalexins from crucifers : probing detoxification pathways in <i>Sclerotinia sclerotiorum</i>Hossain, Mohammad 10 April 2007 (has links)
This thesis investigates two aspects of phytoalexin metabolism by the phytopathogenic fungus <i>Sclerotinia sclerotiorum</i> (Lib) de Bary: (i) determination of detoxification pathways of structurally different molecules; (ii) design and synthesis of potential inhibitors of enzyme(s) involved in detoxification steps.<p>First, the transformations of important cruciferous phytoalexins by the economically important stem rot fungus, <i>S. sclerotiorum</i>, were investigated. During these studies a number of new metabolic products were isolated, their chemical structures were determined using spectroscopic techniques, and further confirmed by synthesis. The metabolic products did not show detectable antifungal activity against <i>S. sclerotiorum </i> which indicated that these metabolic transformations were detoxification processes. Overall, the results of these transformations suggested that <i>S. sclerotiorum</i> produces various enzymes that can detoxify cruciferous phytoalexins via different pathways. While the detoxifications of strongly and moderately antifungal phytoalexins such as brassilexin, sinalexin, and 1-methoxybrassinin were fast and led to glucosylated products, the transformations of the weakly antifungal phytoalexins brassicanal A, spirobrassinin and 1-methoxyspirobrassinin were very slow and yielded non-glucosylated compounds.<p>Next, the design of potentially selective inhibitors of the brassinin detoxification enzyme, BGT, was sought. Two sets of potential inhibitors of BGT were designed: (i) a group was based on the structure of brassinin, where the indole ring of brassinin was replaced with benzofuran, thianaphthene, 7-azaindole and pyrazolo[1,5-a]pyridine and/or the position of side chain was changed from C-3 to C-2; and (ii) another group based on the structure of camalexin where the thiazole ring of camalexin was replaced with a phenyl group. The syntheses and chemical characterization of these potential detoxification inhibitors, along with their antifungal activity, as well as screening using fungal cultures and cell-free extracts of <i>S. sclerotiorum</i>, were examined. The results of these screening indicated that 3-phenylindoles, 3-phenylbenzofuran, 5-fluorocamalexin, methyl (indol-2-yl)methyl-dithiocarbamate, methyl (benzofuran-3-yl)methyldithiocarbamate and methyl (benzo-furan-2-yl)methyldithiocarbamate could slow down the rate of detoxification of brassinin in fungal cultures and also in cell-free extracts of <i>S. sclerotiorum</i>. Among the designed compounds, 3-phenylindole appeared to be the best inhibitor both in fungal cultures and in cell-free extracts. Metabolism studies of all the designed compounds using fungal cultures of <i>S. sclerotiorum</i> indicated that they were metabolized by <i>S. sclerotiorum</i> to glucosyl derivatives, although at much slower rates.<p>It is concluded that some inhibitors that can slow down the rate of metabolism of brassinin could be good leading structures to design more active inhibitors of BGT.
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Molecular insights into arabidopsis response to Myzus persicae sulzer (green peach aphid)Pegadaraju, Venkatramana January 1900 (has links)
Doctor of Philosophy / Department of Biology / Jyoti Shah / Phloem-feeding insects like aphids feed on a variety of crop plants and limit plant productivity. In addition they are vectors for important plant viruses. Efforts to enhance plant resistance to aphids have been hampered by lack of sufficient understanding of mechanisms of plant defense against aphids. I have utilized a plant-aphid system consisting of the model plant Arabidopsis thaliana and the generalist aphid, Myzus persicae Sulzer (green peach aphid [GPA]), to study plant response to aphids. These studies have demonstrated an important role of premature leaf senescence in controlling aphid growth in Arabidopsis. Molecular and physiological studies suggest that the Arabidopsis PAD4 (PHYTOALEXIN DEFICIENT 4) gene modulates the GPA feeding-induced senescence process. Furthermore, in comparison to the wild type plants, GPA growth was higher on pad4 mutant plants, suggesting an important role for PAD4 in plant defense against GPA. In contrast, constitutive expression of PAD4 in transgenic Arabidopsis enhanced basal resistance against GPA. Unlike its involvement in plant defense against pathogens, the role of PAD4 in Arabidopsis resistance to GPA is independent of its involvement in phytoalexin biosynthesis and of its interaction with EDS1, a PAD4-interacting protein. Instead, the heightened resistance to GPA in these PAD4 constitutively expressing plants was associated with the rapid activation of leaf senescence. The association of premature leaf senescence in basal defense against GPA is supported by our observation that in comparison to the wild type plant, GPA growth was restricted on the Arabidopsis hypersenescence mutants, ssi2 and cpr5.
Gene expression studies suggested some overlap between plant responses to pathogens and aphids, for example, activation of genes associated with the salicylic acid (SA) signaling pathway. However, the characterization of aphid performance on Arabidopsis SA biosynthesis and signaling mutants have ruled out the involvement of SA signaling in controlling aphid growth.
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