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Zugang zu Agrar- & Pharmawirkstoffen durch organische Synthese / Design und Synthese von Spinosynanaloga und Hsp47-Inhibitoren sowie enantioselektive Totalsynthese des Naturstoffes Linoxepin / Access to agricultural and pharmaceutical active ingredients by organic synthesis / Design and Synthesis of Spinosyn analogues and Hsp47 inhibitors as well as enantioselective total synthesis of the natural product LinoxepinBiller, Simon 10 June 2015 (has links)
Diese Arbeit beinhaltet die Modellierung von neuartigen Spinosynanaloga über zwei aufeinanderfolgende Heck-Reaktionen und die Modifizierung einer beta-selektiven Glycosylierungsmethode sowie die Synthese von sechs neuen potentiellen Hsp47-Inhibitoren, die auf neuen Forschungsergebnissen basieren. Darüber hinaus wird ein enantioselektiver Zugang zu dem Lignan Linoxepin in elf Stufen mit der höchsten bisher erreichten Gesamtausbeute vorgestellt. Als Schlüsselschritte dienen hier eine Domino-Carbopalladierung-Heck-Reaktion, eine asymmetrische Hydroborierung und eine oxidative Lactonisierung.
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Structural characterization of post-PKS enzymes involved in spinosyn biosynthesisIsiorho, Eta Amauche 07 April 2015 (has links)
Saccharopolyspora spinosa is a rare actinomycete that synthesizes the secondary metabolite spinosyn A, which is an active ingredient in several important commercial insecticides. Spinosyn aglycone formation occurs via a type I polyketide synthase. After release of the polyketide chain from the synthase, various tailoring enzymes modify the aglycone core. These unique enzyme transformations result in unusual structural characteristics found in spinosyn A. The enzymes SpnG, SpnP, SpnF and SpnL each perform a key reaction during post-PKS processing. The work presented in this dissertation focuses on the structural determination and analysis of SpnG, SpnP, SpnF and SpnL. SpnG, which naturally catalyzes the 9-OH rhamnosylation of spinosyn, is capable of adding diverse sugars to the spinosyn aglycone from TDP-hexoses, such as TDP-glucose. However, the substitution of UDP-glucose for TDP-glucose as the donor substrate is known to result in a >60,000-fold reduction in k [subscript cat]. The structure of SpnG at 1.65 Å resolution, the 1.86 Å resolution structure of SpnG bound to TDP, and the 1.70 Å resolution structure of SpnG bound to AGL were determined. The SpnG-TDP complex reveals how SpnG employs N202 to discriminate between TDP- and UDP-sugars. The SpnG-AGL complex shows that SpnG binds the acceptor substrate primarily through hydrophobic interactions and implicates H13 as the potential catalytic base. A model for how rhamnose binds in the active site was constructed to elucidate which features enable SpnG to transfer diverse hexoses. SpnP transfers forosamine from a TDP-D-forosamine donor substrate to a spinosyn pseudoaglycone acceptor substrate. The structures of SpnP and its complex with TDP were determined to 2.50 Å and 3.15 Å resolution, respectively. SpnP possesses a structural feature that has only been previously observed in a related glycosyltransferase, which employs an auxiliary protein that aids in its catalysis. This unique feature may be a used as a predictive motif of glycosyltransferases that interact with an auxiliary protein. SpnF and SpnL are two novel S-adenosyl-L-methionine dependent cyclases. Structural data was utilized in order to gain insight into the unusual cycloaddition catalyzed by the putative Diels-Alderase and Rauhut-Currierase, SpnF and SpnL, respectively. Together these structures provide valuable insights into the unusual mechanisms involved in spinosyn biosynthesis. / text
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Mechanistic investigations of SpnF- and SpnL-catalyzed cyclizations in the biosynthesis of spinosyn AKim, Nam Ho, 1975- 03 March 2015 (has links)
Spinosyn A is a particularly interesting natural product due to its structural complexity and potent insecticidal activity. The biosynthetic pathway of spinosyn A is interesting as it has two unusual features, the SpnF-catalyzed (4+2) cycloaddition and the SpnL-catalyzed cyclization to produce the perhydro-as-indacene core. The work described in this dissertation focuses on elucidating the mechanisms of the SpnF- and SpnL-catalyzed reactions. SpnF has attracted significant interest as a possible Diels-Alderase. To explain how SpnF catalyzes the formation of cyclohexene ring, three plausible mechanisms have been proposed, the Diels-Alder reaction mechanism, the ionic rearrangement mechanism, and the biradical rearrangement mechanism. Kinetic isotope effect studies were performed using four deuterium-labeled mechanistic probes, specially the C4-D, C7-D, C11-D, and C12-D analogs. Currently, the ionic rearrangement mechanism can be excluded, based on the results using the C4-D and C7-D analogs. In addition, how SpnF accelerates the reaction was studied to assess the contribution of an entropic x preorganization compared to enthalpic transition state stabilization. To measure the relative rate enhancements due to structural perturbations, three mechanistic probes were synthesized, the linear analog, the C13-14 Unc analog, and the C2-3 Unc analog. Unfortunately, the linear analog and C13-14 Unc analog didn’t show any turnover activity under either non-enzymatic or enzymatic conditions. Thus, no conclusion could be drawn from incubation with these substrate analogs. Mechanistic studies of SpnL-catalyzed cyclization were devoted to differentiating between the Rauhut-Currier type mechanism and the Michael addition mechanism. Biochemical studies using the C13-F analog as a mechanism-based inhibitor showed the formation of a covalent adduct with SpnL, which is consistent with the Rauhut-Currier type mechanism. Additional experimental data obtained from isotope trace experiments and kinetic isotope effect studies using C12-D analog supports the Rauhut-Currier type mechanism. Biochemical studies concerning the role of SAM in SpnF and SpnL showed that SAM is required for the activity of SpnL, and were inconclusive for SpnF. SpnL mutant studies showed that Cys60 and Glu96 may be important for the catalysis of SpnL. Chemoenzymatic total synthesis of spinosyn A was completed by chemical etherification of 17-pseudoaglycone and D-forosamine. / text
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Synthetic approaches to investigate the chemical mechanism in the biosynthesis of natural productsChoi, Sei Hyun 22 September 2014 (has links)
The study of the biosynthetic logic of natural products has established itself to be one of the more exciting areas of research and have become an important part of modern drug discovery and development efforts. Therefore, understanding the pathway and the chemical mechanism of the biosynthesis of natural products is important in that knowledge on these processes can be applied for combinatorial biosynthesis to generate new natural product derivatives with enhanced biological activities. In addition to the practical value, a lot of unprecedented chemical mechanisms can be found in the enzymes involved therein, which will significantly advance our understanding of enzyme catalysis. The works described in this dissertation focus on elucidating the chemical mechanism of a number of enzymes involved in natural product biosynthesis by utilizing the versatility of synthetic chemistry to prepare enzyme substrates and mechanistic probes. First, SpnF and SpnL responsible for constructing the tetracyclic architecture of spinosyn A have been investigated. In vitro assay revealed the importance of the highly conjugated system for the [4+2]cycloaddition catalyzed by SpnF. Biochemical studies strongly suggest that SpnL employs the Rauhut-Currier mechanism for the second cyclization step in the biosynthesis of spinosyn A. It was also demonstrated that SpnL requires SAM for its activity. Second, a radical SAM enzyme DesII involved in the desosamine pathway has been investigated. It has been demonstrated that DesII can catalyze the dehydrogenation of TDP-D-quinovose as well as the deamination of the natural substrate, which makes DesII unique among radical SAM enzymes. In vitro assays revealed that DesII requires stoichiometric amount of SAM, which. EPR study firmly established the intermediacy of a C-3 radical in the DesII-catalyzed dehydrogenation of TDP-D-quinovose. Finally, the chemical mechanism of AXS responsible for the biosynthesis of UDP-apiose has been investigated. In vitro activity assay using UDP-2F-glucuronic acid showed that the analog is a competitive inhibitor of AXS. A coupled assay strategy was also developed to investigate the chemical mechanism of AXS in the reverse direction. In addition, the stereospecificity of two separate hydride transfer steps of AXS reaction has been firmly established. / text
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Investigation of the post-polyketide synthase (PKS) modifications during spinosyn A biosynthesis in Saccharopolyspora spinosaKim, Hak Joong 13 November 2013 (has links)
Diverse biological activities of polyketide natural products are often associated with specific structural motifs, biosynthetically introduced after construction of the polyketide core. Therefore, investigation of such "post-polykektide synthase (PKS)" modifications is important, and the accumulated knowledge on these processes can be applied for combinatorial biosynthesis to generate new polyketide derivatives with enhanced biological activities. In addition to the practical value, a lot of unprecedented chemical mechanisms can be found in the enzymes involved therein, which will significantly advance our understanding of enzyme catalysis. The works described in this dissertation focus on elucidating a number of post-PKS modifications involved in the biosynthesis of an insecticidal polyketide, spinosyn A, in Saccharopolyspora spinosa. First, three methyltransferases, SpnH, SpnI, and SpnK, responsible for the modification of the rhamnose moiety, have been investigated to verify their functions and to study how they are coordinated to achieve the desired level of methylation of rhamnose. In vitro assays using purified enzymes not only established that SpnH, SpnI, and SpnK are the respective rhamnose 4ʹ-, 2ʹ-, and 3ʹ-O-methyltransferase, but also validated their roles in the permethylation process of spinosyn A. Investigation of the order of the methylation events revealed that only one route catalyzed by SpnI, SpnK, and SpnH in sequence is productive for the permethylation of the rhamnose moiety, which is likely achieved by the proper control of the expression levels of the methyltransferase genes involved in vivo. The key structural feature of spinosyn A is the presence of the unique tetracyclic architecture likely derived from the monocyclic PKS product. To elucidate this "cross-bridging" process, which had been hypothesized to involve four enzymes, SpnF, SpnJ, SpnL, and SpnM, the presumed polyketide substrate was chemically synthesized using Julia-Kocienski olefination, Stille cross-coupling, and Yamaguchi macrolactonization as key reactions. Incubation of the synthesized substrate with SpnJ produced a new product where the 15-OH group of the substrate is oxidized to the ketone. Next, it was demonstrated that incubation of this ketone intermediate with SpnM produces a tricyclic compound, via a transient monocyclic intermediate with high degree of unsaturation. Whereas it was initially thought that SpnM catalyzes both dehydration and [4+2] cycloaddition in sequence, detailed kinetic analysis revealed that SpnM is only responsible for the dehydration step, and the [4+2] cycloaddition step is indeed catalyzed by SpnF. Finally, successful conversion of the tricyclic intermediate to the tetracyclic core was demonstrated using SpnL. Proposed chemical mechanisms of SpnF and SpnL, Diels-Alder and Rauhut-Currier reactions, respectively, are interesting because enzymes capable of catalyzing these reactions have yet to be characterized in vitro. This work not only establishes the biosynthetic pathway for constructing the spinosyn tetracyclic core, but also epitomizes the significance of the post-PKS modification as a rich source of new enzyme catalysis. / text
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