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1	Transkriptionelle, metabolische und physiologische Anpassung nach Selbstintoxikation mit reaktiven Sekundärstoffen: die Glukosinolat-Bombe in Arabidopsis thaliana / Transcriptional, metabolic and physiological adaptation after self-intoxication with reactive secondary substances: the glucosinolate bomb in Arabidopsis thaliana Ferber, Elena January 2019 (has links) (PDF) In Brassicaceae werden bei einer Gewebszerstörung unreaktive Glukosinolate durch das Enzym Myrosinase hydrolysiert. Es entstehen reaktive Substanzen wie Isothiocyanate (ITCs). Da diese Reaktion sehr schnell erfolgt wird sie auch als Senföl-Glukosid-Bombe bezeichnet. In Arabidopsis thaliana erfolgt nach Verwundung und Pathogeninfektion eine massive Akkumulation des ITCs Sulforaphan (SF), welches eine reaktive elektophile Spezies (RES) darstellt. Zu der Gruppe der RES zählen auch einige Oxylipine mit einer α,β-ungesättigten Carbonylgruppen wie 12-oxo-Phytodiensäure (OPDA) oder Phytoprostan A1 (PPA1). Die Fähigkeit der kovalenten Modifikation von Peptiden und Proteinen gilt als essentiell sowohl für die toxischen als auch die Gen-induzierenden Eigenschaften der RES. Neben ihrer Reaktivität spielt auch die Lipophilie eine Rolle für die Fähigkeit über Membranen zu diffundieren und unspezifisch an Proteine zu binden. Die in der vorliegenden Arbeit durchgeführten Transkriptomanalysen an Arabidopsis-Keimlingen mit sub-toxischen Konzentrationen von SF, Benzylisothiocyanat (BITC) und dem Oxylipin Prostaglandin A1 (PGA1) zeigten, dass strukturell sehr verschiedene RES einen gemeinsamen Satz von 55 Genen induzieren. Unter diesen befanden sich verschiedene Hitzeschock-, Stressassoziierte- und Detoxifizierungsgene. Diese Ergebnisse deuten darauf hin, dass die Aktivierung über eine Muster-spezifische Erkennung der RES erfolgt. Als einen möglichen Mechanismus der RES-vermittelten Geninduktion wird die Regulation durch die Veränderung des zellulären Redox-Potentials als Folge kovalenter Modifikation von GSH durch RES diskutiert. Die Untersuchung der GSH-Gehalte sowie des Redox-Potential nach Behandlung mit sub-toxischen RES-Konzentrationen in Arabidopsis-Keimlingen zeigte jedoch unter den getesteten Bedingungen keine Veränderung. Neben dem Erkennungs- und Signaltransduktionsmechanismus ist auch die biologische Bedeutung von RES für die Vermittlung einer Stresstoleranz noch weitgehend unklar. Durch die Untersuchung der Genexpression in Arabidopsis-Pflanzen nach Verwundung konnte gezeigt werden, dass eine wundinduzierte Akkumulation von SF zur Induktion einiger Gene der Hitzeschockreaktion (HSR) im Wildtyp, jedoch nicht in der myrosinase-defiziten tgg1tgg2-Mutante führte. Auch in der Transkriptomanalyse war nach RES-Gabe ebenfalls eine starke Induktion hitze-responsiver Gene, deren Regulation über den Masterregulator dem Hitzeschock-TF A1 vermittelt wird, zu beobachten. Besonders die Induktion der HSPs, welche als Chaperone fungieren und damit Thiolgruppen von Proteinen vor Modifikation schützen können, haben vermutlich bei chemischer Intoxikation protektive Eigenschaften für die Zellen. Tatsächlich zeigte sich unter den gewählten Bedingungen die hsfa1a,b,d,e-Mutante empfindlicher gegenüber ITCs als der Wildtyp. Die Fähigkeit, eine HSR ausbilden zu können, scheint in Arabidopsis bei chemischer Intoxikation eine bedeutende Rolle zu spielen. Eine Vorbehandlung mit RES wie SF, BITC oder dem HSP90-Inhibitor Radicicol in Arabidopsis-Keimlingen konnte eine Schutzwirkung vor chemischer Intoxikation vermitteln. Dies erfolgte jedoch nicht nach Behandlung mit moderater Hitze (zwei Stunden, 37 °C). Somit scheint die HSR alleine nicht ausreichend für den Aufbau eines effektiven Schutzes vor BITC-Intoxikation zu sein. Als metabolische Antwort von Arabidopsis-Keimlingen auf Intoxikation mit RES konnte eine konzentrationsabhängige Senkung der maximalen Quantenausbeute am Photosystem II (PSII), sowie gleichzeitig eine Akkumulation an TAG-Spezies beobachtet werden. Diese metabolische Reaktion ist in der Literatur bereits als Schutz gegen Hitzestress beschrieben. Die Bedeutung der TAG-Akkumulation nach chemischem ITC-Stress ist noch unklar. / In Brassicaceae, unreactive glucosinolates are hydrolyzed by the enzyme myrosinase during tissue destruction. Reactive substances such as isothiocyanates (ITCs) are formed. Since this reaction takes place very quickly, it is also called mustard oil bomb. In Arabidopsis thaliana, after wounding and pathogen infection, a massive accumulation of the ITC Sulforaphan (SF) occurs, which is a reactive electophilic species (RES). The group of RES also includes some oxylipins with a α,β-unsaturated carbonyl group such as 12-oxo-phytodienoic acid (OPDA) or phytoprotane A1 (PPA1). The ability to covalently modify peptides and proteins is considered essential for the toxic and gene inducing properties of RES. In addition to their reactivity, lipophilia also plays a role in the ability to diffuse across membranes and bind unspecifically to proteins. The transcriptome analyses performed on Arabidopsis-seedlings with sub-toxic concentrations of SF, benzylisothiocyanate (BITC) and oxylipin prostaglandin A1 (PGA1) showed that structurally very different RES induce a common set of 55 genes. Among the induced genes were several heat shock, stress associated and detoxification genes. These observations suggest that activation is via pattern-specific recognition of RES. As a possible mechanism of RES-mediated gene induction, regulation by alteration of the cellular redox potential as result of covalent modification of GSH by RES is discussed. However, the study of GSH levels and redox potential after treatment with sub-toxic RES concentrations in Arabidopsis-seedlings showed no change under the tested conditions. In addition to the recognition and signal transduction mechanism for RES, the biological significance of RES for the mediation of stress tolerance is still largely unclear. By studying the gene expression of Arabidopsis-plants after wounding, it was shown that wound induced accumulation of SF led to the induction of some genes of heat shock response (HSR) in the wild type, but not in the myrosinase-deficient tgg1tgg2-mutant. Also in transcriptome analysis a strong induction of heat-responsive genes could be observed after RES administration, whose regulation is mediated by the master regulator of the heatshock-TF A1 (HSFA1). In particular, the induction of HSPs, which act as chaperones and can thus protect thiol groups of proteins from modification, presumably have protective properties for the cells during chemical intoxication. In fact, under the conditions tested, the hsfa1a,b,d,e-mutants were more sensitive to ITCs than the wild type. The ability to form HSR seems to play an important role in chemical intoxication in Arabidopsis. Pretreatment with RES such as SF, BITC or the HSP90 inhibitor radicicol in Arabidopsis-seedlings could mediate a protective effect against chemical intoxication. However, this was not done after treatment with moderate heat (two hours, 37 °C). Thus, HSR alone does not seem to be sufficient to provide effective protection against BITC intoxication. As a metabolic response of Arabidopsis-seedlings to intoxication with RES, a concentration-dependent reduction of the maximum quantum yield at the photosystem II (PSII), as well as an accumulation of TAG species could be observed. This metabolic reaction is already described in the literature as protection against heat stress. The significance of TAG accumulation after chemical stress in the form of ITC intoxication is still unclear. Ackerschmalwand Glucosinolate Isothiocyanate ddc:580
2	Charakterisierung der Funktion von Branched-Chain Aminotransferasen und Isopropylmalat Isomerasen im Primär- und/oder Sekundärmetabolismus in Arabidopsis thaliana Knill, Tanja, January 2008 (has links) Ulm, Univ., Diss., 2008.
3	Kopplungsmethoden in der Naturstoffanalytik : Untersuchungen an Arabidopsis thaliana und an Ancistrocladus-Pflanzen Kajahn, Inga January 2008 (has links) Würzburg, Univ., Diss., 2008
4	The role of the glucosinolate-myrosinase system for the interaction of Brassicaceae with the turnip sawfly Athalia rosae(L.) / Die Rolle des Glucosinolat-Myrosinase Systems bei der Interaktion von Brassicaceae mit der Rübsenblattwespe Athalia rosae (L.) Travers-Martin, Nora Verena January 2007 (has links) (PDF) Brassicaceae and a few related plant families are characterized by possession of the glucosinolate-myrosinase system. Glucosinolates are amino-acid derived allelochemicals which are hydrolysed upon tissue damage by myrosinase enzymes to produce various degradation products which can be toxic for generalist insects. The larvae of the crucifer-specialist Athalia rosae, the turnip sawfly, sequester glucosinolates into their haemolymph. The role of the glucosinolate-myrosinase system for the interaction of the turnip sawfly with Brassicaceae was examined in this study from two different perspectives: variation within individual plants and between plant species. The plant responses to the feeding by herbivores and the short-term effects this induction had on insect behaviour were investigated in white mustard. Furthermore, plants can use multiple defences. Hence correlations of glucosinolates and myrosinase activities with other defences and nutritional quality and their long-term effects on the development of the insects were investigated in seven different plant species. / Die Brassicaceen und einige nah verwandte Pflanzenfamilien zeichnen sich durch den Besitz des Glucosinolat-Myrosinase Systems aus. Glucosinolate sind von Aminosäuren abgeleitete Allelochemikalien, die nach Gewebezerstörung von Myrosinaseenzymen hydrolysiert werden. Die entstehenden Abbauprodukte wirken auf generalistische Insekten toxisch. Larven der auf Brassicaceen spezialisierten Rübsenblattwespe, Athalia rosae, sequestrieren Glucosinolate in ihre Hämolymphe. In der vorliegenden Studie wird die Rolle des Glucosinolat-Myrosinase Systems für die Interaktion von Brassicaceen mit der Rübsenblattwespe aus zwei unterschiedlichen Perspektiven untersucht: Variationen innerhalb einzelner Pflanzen und zwischen verschiedenen Pflanzenarten. Die pflanzliche Antwort innnerhalb einzelner Individuen auf Herbivorenfraß und deren kurzzeitige Auswirkungen auf das Insektenverhalten wurden am Weißen Senf untersucht. Des Weiteren nutzen Pflanzen multiple Abwehrmethoden. Daher wurden Korrelationen des Glucosinolat-Myrosinase Systems mit anderen Abwehrmethoden und mit dem Nährstoffgehalt der Pflanzen sowie deren langfristige Effekte auf die Entwicklung der Insekten an sieben verschiedenen Pflanzenarten untersucht. Glucosinolate Chemische Ökologie Myrosinase Insekten ddc:580
5	Tissue-specific and environmental regulation of glucosinolate biosynthesis in Arabidopsis thaliana Meagher, Erika J. 26 February 2024 (has links) When exposed to either abiotic or biotic stressors, plants release chemical compounds that can serve as defense mechanisms. For example, plants of the mustard and cabbage family produce a class of anti-herbivory compounds called glucosinolates. In the model mustard plant Arabidopsis thaliana, some glucosinolates are produced from the amino acid tryptophan and are called indole glucosinolates (IGs). Expression of IG synthesis genes is positively regulated by the partially redundant transcription factors, MYB34 and MYB51. Recent studies have shown that these two transcription factors have distinct roles in regulating IG production in different tissues and in mediating responses to different environmental cues. To understand the distinct roles of these transcription factors at a more detailed temporal and spatial level, reporters for CYP79B2, a transcriptional target of both MYB34 and MYB51, were used. CYP79B2-GFP and CYP79B2-GUS reporter expression was analyzed in wild-type and MYB34 and MYB51 mutant plants in response to increased ambient temperature, increased light intensity, ATP exposure, and chitin exposure. Reverse-phase HPLC quantification of IGs was also performed to determine how these transcription factors are mediating the synthesis of IGs in response stressors. Overall, it was found that MYB51 is responsible for the temperature induction of IG production, while increased light intensity has no impact on IG synthesis. Furthermore, ATP appears to induce IG production independently of both MYB34 and MYB51, while chitin does not increase IG synthesis. Taken together, these studies allow us to better understand how plants respond to and defend themselves from different abiotic and biotic stress / 2025-02-26T00:00:00Z Biology Arabidopsis Environmental stress Glucosinolate Transcription factor
6	Thiofonctions insolites sur charpentes saccharidiques / Uncommon thiofunctions on saccharidic frameworks Schleiss, Julie 09 December 2009 (has links) Les glucosinolates (GLs) sont des métabolites secondaires très présents dans la famille des Brassicaceae, une famille de végétaux connus dans l’alimentation humaine pour leurs propriétés gustatives et aussi pour leurs effets chimio-préventifs. La myrosinase (E.C. 3.2.1.147) est la seule enzyme capable d’hydrolyser les GLs. Nous nous sommes intéressés aux produits obtenus lors de cette dégradation - les isothiocyanates (ITCs) mais aussi à la fonction thiohydroximate, et plus particulièrement à la synthèse de nitrones thiofonctionnalisées. La synthèse d’analogues d’ITC ainsi que de certains de leurs thio-conjugués a conduit à une large gamme de molécules permettant de cerner les implications chimio-préventives et les potentiels en bio-activité (notamment contre Plasmodium falciparum). Partant d’observations analytiques relatives à certains GLs comme la glucoraphénine, il a été découvert qu’un thiohydroximate pouvait présenter un caractère nucléophile comparable à celui d’une oxime dans un processus cyclisant du type Grigg. Nous avons dès lors cherché à développer de nouvelles voies d’accès à un système fonctionnel très peu décrit dans la littérature : les N-oxydes de thioimidate (OTI). Une étude de réactivité d’un OTI-modèle a révélé des comportements originaux, en particulier dans des réactions de couplage pallado-catalysées qui ouvrent un accès à des nitrones cycliques originales et peu aisées à préparer par des voies plus classiques. / Glucosinolates (GLs) are widespread secondary metabolites in Brassicaceae, a family of vegetables known in human feeding for their tastes and also for their chemo-prevention effects. Myrosinase (E.C. 3.2.1.147) is the only enzyme able to hydrolyze GLs. We have been interested in products acquired during this degradation - isothiocyanates (ITCs) but also in the thiohydroximate function, and more particularly in the synthesis of thiofunctionalized nitrones. The synthesis of ITC analogues as well as some of their thio-conjugates has led to a broad range of molecules allowing to surround chemo-preventive involvements and potentials in bio-activity (namely against Plasmodium falciparum). Starting from analytical observations related to some GLs such as glucoraphenin, it has been disclosed that a thiohydroximate could display a nucleophilic character comparable to that of an oxime in a Grigg-type cyclic process. We have developed new pathways to a scarcely described functional system : thioimidate N-oxides (OTI). Reactivity studies on a model-OTI have revealed an atypical behaviour, notably in palladium-catalyzed coupling reactions : those open the way to original cyclic nitrones which are not easily available via standard methods. Glucosinolate Isothiocyanate Thiohydroximate N-oxyde de thioimidate Glucosinolate Isothiocyanate Thiohydroximate Thioimidate N-oxide
7	Effects of abiotic growth factors on glucosinolate levels, sensory quality and yield components in cabbage (brassica oleracea group capitata) Radovich, Theodore James Kelly 29 September 2004 (has links) No description available. Agriculture, Plant Culture GLUCOSINOLATE CABBAGE Glucosinolate concentrations cultivar irrigation head development
8	Développement de nouvelles approches méthodologiques en Chromatographie de Partage Centrifuge en vue de la purification de molécules d'intérêt Toribio, Alix. Nuzillard, Jean-Marc. Renault, Jean-Hugues. January 2007 (has links) (PDF) Reproduction de : Thèse de doctorat : Pharmacie. Pharmacognosie : Reims : 2007. / Bibliographie multiples.
9	Variabilität aliphatischer Glucosinolate in Arabidopsis thaliana-Ökotypen und deren Einfluss auf die Wirtspflanzeneignung von zwei folivoren Insektenarten Rohr, Franziska January 2009 (has links) Zugl.: Berlin, Humboldt-Univ., Diplomarbeit
10	Genetic Basis for Glucosinolate Hydrolysis in E. coli O157:H7 by Glycoside Hydrolase Action and Nature of its Adaptation to Isothiocyanate Toxicity Cordeiro, Roniele P 30 June 2015 (has links) Ready-to-eat meat products such as dry-fermented sausages have been associated with foodborne outbreaks despite the multiple hurdles used in the manufacturing process to prevent growth of pathogens. As a result, new strategies such as natural products with antimicrobial activity are being used to control pathogens of importance like Escherichia coli O157:H7. This study investigated how different concentrations and sources of mustard can influence its antimicrobial activity against E. coli O157:H7 in dry-fermented sausage, as well as the contribution of residual myrosinase enzyme in mustard to this process. The genetic basis for the degradation of mustard glucosinolate by E. coli O157:H7, which is associated with the antimicrobial action of mustard, was also characterized. The ability of E. coli O157:H7 to withstand inhibitory allyl isothiocyanate (AITC) concentrations and the role of the two-component BaeSR system as a defense mechanism against AITC was also investigated. Results showed that 4% (w/w) deodorized yellow mustard powder was effective to control E. coli O157:H7 in dry-fermented sausage at 28 d. The presence of endogenous plant myrosinase in the mustard powder or meal enhanced E. coli O157:H7 reduction rates. Fully-deodorized, deoiled, yellow mustard meal as low as 2% (w/w) containing either 0.1% or 0.2% of residual plant myrosinase achieved the same results as 4% (w/w) mustard powder also containing similar residual myrosinase. Regardless of the type of mustard, the antimicrobial activity of yellow mustard derivatives were more pronounced than those of Oriental mustard. The initial genetic assessment through in silico analysis found similarity between plant myrosinase and enzymes encoded by genes (bglA, ascB, and chbF) from β-glucosidase families in E. coli O157:H7 strains. After disruption of these genes using lambda-red replacement, single (∆bglA, ∆ascB, ∆chbF) and double (∆bglAascB, ∆chbFascB, ∆chbFbglA) mutant strains were created and assessed for glucosinolate degradation. The comparison of the gene expression profiles and changes in the extent of sinigrin degradation by different mutants suggested that ascB have a prominent role in the degradation of this β-glucoside by E. coli O157:H7. E. coli O157:H7 did not develop resistance to AITC, the essential oil formed from sinigrin degradation that is responsible for the antimicrobial activity of Oriental mustard. Mustard Glucosinolate Isothiocyanate Myrosinase E. coli O157:H7 Glycoside hydrolase genes

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