Browsing by Subject "Natural product"
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Item Application of the Moore rearrangement to the synthesis of 1,4-dioxygenated xanthones and efforts toward the total synthesis of lundurine B(2012-12) Nichols, Alexander Lindsey; Martin, Stephen F.; Iverson, Brent; Willson, C. G.; Kerwin, Sean; Keatinge-Clay, AdrianA novel application of the Moore rearrangement was successfully developed and applied to the synthesis of 1,4-dioxygenated xanthones that would have been difficult to obtain otherwise. The 1,4-dioxygenated xanthone moiety is found in several naturally occurring, biologically active compounds. Several methods by which to obtain the 1,4-dioxygenated xanthone core have been reported; however, high step counts, low yields, and harsh reaction conditions preclude the use of these methods to complex xanthone natural products. Using the Moore rearrangement as a key step in the synthetic sequence has allowed us to prepare several xanthone natural products quickly and more efficiently than what is possible with the prior art. Using the Martin group’s prior experience with the application of ring closing metathesis (RCM) to the field of alkaloid natural product synthesis, the preparation of lundurine B was undertaken. Key features of the proposed synthesis to lundurine B include the formation of a cyclopropane ring by the formation pyrazoline intermediate via [3+2] dipolar cycloaddition followed by dinitrogen extrusion. A second key step in the proposed sequence to lundurine B is a double RCM to form a five- and eight-membered ring in a single operation. While double RCM strategies have been applied to several elegant natural product syntheses, the formation of a five- and eight-membered ring in a single sequence has not been reported. Should the double RCM strategy prove successful for lundurine B, the conditions could in principle be applied to other structurally related natural products.Item Efforts towards the total synthesis of the stemofoline alkaloids utilizing a novel 1,3-dipolar cycloaddition reaction and application of the Pauson-Khand reaction as a novel entry into bridged azabicyclic ring systems(2011-08) Shanahan, Charles S.; Martin, Stephen F.; Krische, Michael J.; Anslyn, Eric V.; Whitman, Christian P.; Brodbelt, Jennifer S.A novel application of the Pauson-Khand reaction was applied to the synthesis of a series of bridged azatricyclic piperazines. This method represents the first application of the Pauson-Khand reaction to synthesize azabridged scaffolds. The ubiquity of bridged azabicyclic ring systems in biologically active natural product skeletons has provided the synthetic chemist with a wealth of opportunity for development over the last century. To this day, the development of new methodologies to tackle these structurally challenging systems remains at the forefront of synthetic chemistry. During our efforts to achieve a total synthesis of the stemofoline alkaloids, we have thus far developed a novel and scalable synthetic strategy to access the fully functionalized caged azatricyclic core of these challenging alkaloids. The overall synthetic strategy we have implemented began with the commercially available and affordable 2-deoxy-D-ribose as a chiral starting material. Furthermore, we have developed a novel 1,3-dipole cascade cycloaddition, which was successfully employed as the key step in the construction of the bridged azatricyclic core of the stemofoline alkaloids.Item New Strategies in the Localization of Natural Product Biosynthetic Pathways and Achieving Heterologous Expression(2011-02-22) Kim, Eun JinNatural products have long furnished medical science playing a significant role in drug discovery and development. Their importance notwithstanding, it is estimated that less than 1% of microorganisms can be cultivated from environmental sources using standard laboratory techniques. It is therefore necessary to develop biochemical and genetic techniques to access these uncultivable genomes. Here as a point of departure toward this goal, two cDNA libraries of two microorganisms were constructed along with five fosmid libraries with DNA isolated from marine environmental samples. We describe the construction of cDNA libraries from marine microbial species and detail experiments to exploit these libraries for their natural product biosynthetic pathways and other metabolic enzymes they harbor. However, no useful biosynthetic pathways were detected within the cDNA libraries. Genetic selection by complementation was additionally explored as a method to identify and localize biosynthetic gene clusters within marine microbial DNA libraries. Genetic selection is a fast and economic method which utilizes selection of a part of a pathway to represent the presence of an entire pathway for the complementation of known mutant strains. We describe genetic selection to localize biotin biosynthetic pathways of Hon6 (Chromohalobacter sp.) as a proof of principle experiment for the identification and localization of biosynthetic pathways in general. Instead of developing purification methods or manipulating cultivation conditions, large fragments of non-culturable bacterial genomes can be cloned and expressed using recombinant DNA technology. A strong transcriptional promoter to control high-level gene expression is required in recombinant expression plasmids. We aimed to develop new tools to control gene expression through the use of riboswitches. Riboswitches are metabolite-sensing ribonucleic acid (RNA) elements that possess the remarkable ability to control gene expression. The thiamine pyrophosphate (TPP) riboswitch system was chosen as it will enable use of E. coli as a suitable host strain. This system is particularly attractive because it has one of the simplest structures among the riboswitches elucidated to date. The use of the TPP riboswitch will also enable modulation of pathway gene expression by varying the TPP coccentration as many gene products are toxic. The violacein gene cluster from Chromobacterium violaceum was selected and placed under the control of this riboswitch. We describe modulation of heterologous gene expression by the ThiC/Riboswitch and detail experiments to investigate the expression and manipulation of the gene cluster under various promoters.Item Synthetic approaches to investigate the chemical mechanism in the biosynthesis of natural products(2012-08) Choi, Sei Hyun; Liu, Hung-wen, 1952-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.Item Towards preparative in vitro enzymatic synthesis of new polyketide metabolites(2013-08) Hughes, Amanda Jane; Keatinge-Clay, Adrian TristanModular polyketide synthases (PKSs) are the largest enzymes known to man and are responsible for synthesizing some of the most important human medicines. Their ability to construct stereochemically-rich carbon chains containing diverse substituents has inspired the biosynthetic community to engineer these factories for the in vitro synthesis of a small library of polyketide compounds. New complex polyketides are discovered every year, yet the lack of compound prohibits characterization and testing of these new compounds for medicinal properties. Smaller polyketide compounds generated in vitro could be organically manipulated to generate larger, more complex polyketide natural products and natural product analogs. Chemoenzymatic approaches like this would be extremely beneficial to the scientific community; however, there are still obstacles that must be overcome before the use of PKS for the preparative synthesis of an in vitro generated polyketide library would prove fruitful: purchasing substrates such as methylmalonyl-CoA is cost-prohibitive, PKSs are often difficult to express and purify, and the products generated are typically nonchromophoric. The use of a malonyl-CoA ligase from Streptomyces coelicolor (MatB) was investigated for the enzymatic synthesis of polyketide extender units such as methylmalonyl-CoA (Chapter 2). MatB synthesized a total of 5 CoA-linked extender units in vitro: malonyl-, methylmalonyl-, ethylmalonyl-, hydroxymalonyl- and methoxymalonyl-CoA. Two ternary complex structures of MatB with bound product and leaving group were also solved to sub-2Å resolution. MatB generated extender units were employed in the module-catalyzed synthesis of a triketide pyrone. The selectivity of a PKS module to incorporate a variety of side chains into triketide pyrones was also investigated (Chapter 3). A total of 10 triketide pyrone compounds were synthesized, 5 produced via modular "stuttering" and one possessing a terminal alkyne chemical handle. Lastly, nonchromphoric polyketide products were made visible upon copper(I)-catalyzed azide alkyne cycloaddition (CuAAC) with fluorescent sulforhodamine B azide revealing insights into in vitro reactivites of a PKS module (Chapter 4). The work described in this dissertation has helped advance the scientific community towards procuring an in vitro synthesized polyketide library for future synthetic applications.