Exploring and exploiting selectivity in rhodium-catalysed hydroacylation reactions

Poingdestre, Sarah-Jane

January 2012

Chapter 1 is an overview of the key developments in rhodium-catalysed hydroacylation. The main focus of this chapter is the use of various chelation strategies for the stabilisation of key rhodium-acyl intermediates. In addition, the more recent emergence of regioselective hydroacylation processes has been highlighted. Chapter 2 discloses the branched-selective intermolecular hydroacylation of 1,3-dienes and S-chelating aldehydes to afford synthetically useful 1,5-dione products. The evaluation of a number of different phosphine ligands for this process identifies a correlation between ligand bite angle and reaction regioselectivity. Chapter 3 discusses the development of a linear-selective hydroacylation process for previously challenging alkyne substrates. This, in combination with a complementary branched-selective process, provides a ligand-controlled regioselectivity switch between the branched and linear pathways. Finally, Chapter 4 details efforts towards the development of multicomponent, tandem processes through exploitation of our synthetically useful branched hydroacylation adducts.

546.634

Chiral counter-ion controlled asymmetric electrocyclic reactions

Knipe, Peter Clarke

January 2012

The aim of this project was to develop new catalytic methods to control asymmetry in electrocyclic reactions, and to apply these methods to generate complex molecules. Initial efforts were directed towards the catalysis of anionic 8π electrocyclizations (Chapter 2 and Figure i). 8π electrocyclization was not achieved due to issues with alkene geometry and anion stability. Our efforts were then directed towards using phase-transfer catalysis to generate complex polycyclic compounds via a cascade electrocyclization-1,4-addition (Chapter 3 and Figure ii). Pyrrolidines and indolizidines were generated in excellent yield from simple starting-materials with high levels of stereocontrol. Finally, we investigated the catalysis of a 6π [1,6] electrocyclization to generate dihydroquinolones (Chapter 4 and Figure iii). A novel BINOL-derived copper(II) catalyst was developed, and afforded dihydroquinolones directly from their amine and aldehyde precursors with good yields and enantioselectivities.

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Synthesis of the ABC fragment of pectenotoxin-4

Lipinski, Radoslaw Michal

January 2012

This thesis details the application of two synthetic methodologies, developed by the Donohoe group, to the synthesis of the ABC fragment of pectenotoxin-4, a macrolide marine natural product that consists of 19 stereogenic centres, three tetrahydrofuran rings, one spiroketal and one bicyclic ketal embedded within a 26-membered macrocycle. Pivotal to the developed synthetic route was the utilisation of an unprecedented cascade osmium catalysed oxidative cyclisation for the construction of two THF rings (the BC ring system). After successfully developing a model system for the synthesis of the AB anomeric 6,5 spiroketal, which involved the employment of a hydride shift initiated oxo carbenium ion formation followed by intramolecular spiroketalisation, the developed system was then applied to the fully elaborated synthesis of the ABC fragment. The synthesis of the ABC fragment of pectenotoxin-4 was completed in 20 linear steps, with an overall yield of 3.3%.

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Synthesis and elaboration of heterocycles via palladium-catalyzed C-H functionalization

Gerelle, Maria

January 2012

Chapter 1 is a brief literature review of the most recent progress in the area of C-H functionalization via palladium catalysis. This covers the functionalization of electron deficient arenes and heterocycles with alkenyl and alkyl halides both using inter- and intra-molecular reactions. The chapter also contains an overview of recent work from the Willis group. Chapter 2 presents the functionalization of electron deficient arenes and alkenyl bromides using palladium catalysis, as well as the use of statistical analysis software for optimizing the cross-coupling reaction. Chapter 3 describes the cross-coupling of substituted benzoxazoles, benzothiazole and benzimidazole with a range of alkenyl iodides using palladium catalysis. The reaction can tolerate both (E) and (Z) disubstituted alkenes and tri-substituted alkenyl iodides, with retention of the double bond geometry. Chapter 4 details the synthesis of sultams via an intramolecular C-H functionalization using palladium catalysis. The chapter covers the optimization of the starting material synthesis as well as the cross-coupling reaction. We can access the sulfonamides from cyclohexenone and were able to incorporate a large range of substitution patterns (Scheme 3). Finally, Chapter 5 contains all the experimental details, general considerations and compound data. All the NMR spectra of novel compounds can be found in the appendix.

547.59

Rhodium catalysed hydroacylation reactions in the synthesis of heterocycles

Ylioja, Paul M.

January 2011

Rhodium-catalysed hydroacylation provides a highly atom economic synthesis of ketone products from the combination of aldehydes and multiple bond systems by C-H bond activation. This work evaluates the combination of intermolecular hydroacylation for the synthesis of classical heterocycle precursors and their dehydrative cyclisation to give rise to a range of substituted heterocyclic compounds. Chapter 1 outlines recent developments in the chemistry of hydroacylation. Particular attention is paid to the various chelation strategies employed in intermolecular hydroacylation. Chapter 2 discusses some relevant and recent developments in the field of pyridine and pyrrole synthesis. Having established that β-sulphur chelation controlled hydroacylation can be used to synthesise pyridines in Chapter 3; attention was turned to hydroacylation of propargyl amines in Chapter 4. The methodology was expanded to provide a synthesis of γ-amino enones. The hydroacylation reaction and cyclisation is combined in a procedure that utilises thermal Boc-deprotection and cyclisation to give a range of highly-substituted pyrroles. The regioselectivity of the hydroacylation of propargyl amines is investigated in Chapter 5 by application of statistical Design of Experiments methodology. Optimised conditions were identified with minor improvements in the selectivity of the reaction.

547.59

Catalytic asymmetric carbon-carbon bond formation using alkenes as alkylmetal equivalents

Maksymowicz, Rebecca Marie

January 2014

The development of new methods for carbon-carbon bond formation is a challenging topic at the heart of organic chemistry. Over the past ten years a number of methods for the catalytic asymmetric 1,4-addition of organometallic reagents such as Grignard, organozinc and organoaluminium reagents have been reported. However these reagents suffer from many limitations, including the need for cryogenic temperatures, which prevent their widespread use. Here we have developed a new asymmetric method: the copper-catalysed enantioselective 1,4-addition of alkylzirconium compounds, generated in situM/em>, from alkenes. A general introduction into the formation of carbon-carbon bonds and catalytic asymmetric 1,4-addition reactions is first given. We then focus our attention on hydrometallation reactions and their current use in the addition of alkenyl and alkyl groups in asymmetric 1,4-addition reactions. In Chapter two, we introduce the development of our methodology. We found that by using copper complex <b>(S,S,S)-A</b>, high enantioselectivities can be achieved (up to 96% ee), in the presence of a broad range of functional groups which are often not compatible with comparable methods using pre-made organometallic reagents. The method gives good enantioselectivity at room temperature, in a wide range of solvents, using readily available alkenes. Chapter three discusses the expansion of our method to the 1,4- and 1,6-addition to complex steroids. Modified conditions were then found to enable the addition to &beta;-substituted enones, to form quaternary centres. This is followed by the successful addition to &alpha;,&beta;-unsaturated lactones, another difficult substrate class. All these results gave excellent selectivity. In summary, we have developed a new reaction which offers an alternative to current methods reported in the literature. This robust reaction can tolerate a variety of functional groups and we hope that this will aid in the synthesis of important molecules.

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Isoenzyme specific PFK-2/FBPase-2 inhibition as an anti-cancer strategy

Williams, Jonathan Glyn

January 2013

High aerobic glycolytic capacity is correlated with poor prognosis and increased tumour aggressiveness. 6Phosphofructo-1-kinase catalyses the first irreversible step of glycolysis, and is activated by fructose-2,6-bisphosphate, a product of the kinase activity of four bifunctional isoenzymes, 6-phosphofructo-2-kinase/fructose-2,6-biphosphatase (PFK-2/FBPase-2:PFKFB1-4). These are potential anti-tumour targets, but their individual and collective role requires further investigation. This thesis had three aims; to validate the PFK-2/FBPase-2 isoenzymes as anti-cancer targets, to investigate the requirement for isoenzyme-specific targeting, and to initiate assay development, enabling future identification of novel inhibitors. A panel of cancer cell lines was examined and PFKFB3 and PFKFB4 were confirmed to be the most strongly induced isoenzymes in hypoxia, regulated by HIF-1&alpha;. Basal and hypoxic relative PFKFB3/PFKFB4 expression varied markedly, and three cell lines with varying expression ratios (MCF-7, U87, PC3) were selected for further study. siRNA knockdown of each isoenzyme individually, markedly reduced 2D and 3D cell growth. The effect of PFKFB3 knockdown was consistently more pronounced, particularly in hypoxia. Double PFKFB3/PFKFB4 knockdown was significantly less effective than PFKFB3 knockdown alone. Direct antagonism of PFKFB3 and PFKFB4 on F-2,6-BP concentration was observed, with PFKFB3 exhibiting high kinase activity, as anticipated, and PFKFB4 exhibiting high bisphosphatase activity. The degree of antagonism was dependent on the relative PFKFB3/PFKFB4 expression ratio. Extensive efforts were made to examine the wider metabolic effect of PFKFB3/PFKFB4 on flux towards glycolysis or the pentose phosphate pathway (PPP), including using metabolite, lipid droplet, ¹³C NMR and mass spectrometry assays. No significant change in metabolic flux was detected, the evidence presented therefore suggesting the impact of the antagonistic effects of the isoenzymes on [F-2,6-BP] extends beyond regulation of metabolic flux alone. This study concluded that the most effective therapeutic strategy will be one that involves a PFKFB3-specific inhibitor, preferably hypoxia-targeted. Accordingly, steps were taken to validate and optimise a robust medium-throughput assay system.

616.99

Phosphoramidite ligand design for the enantioselective conjugate addition of alkylzirconium reagents to enones

Roth, Philippe

January 2014

The development of new methods to make carbon-carbon bonds asymmetrically remains a challenge in organic chemistry. Indeed, the development of highly selective methods often proceeds on a trial and error basis. The way chiral information is transferred to the substrate is unclear in many reactions, limiting further development. We focus here on developing an asymmetric conjugate addition of alkylzirconium nucleophiles to Michael acceptors. The development of new phosphoramidite ligands, supported by a computer based model, allowed further development of the reaction. First, existing methods to introduce enantioselectively chirality are described. Then we discuss ligands, and modern ways to parameterise experimental data using computational methods. In chapter two, after discussing the use of alkenes as reagents, especially processes initiated by hydrometallation, we describe a new conjugate addition reaction using cyclic enones that achieves both high yields and levels of enantioselectivity. In chapter three, various applications of phosphoramidite ligands are discussed and we describe the synthesis of a variety of different phosphoramidites and identification of important structural features of these ligands. New, efficient ligands are obtained and a computer model is developed to account for the selectivity of the reaction discussed in chapter two. Chapter four describes the development of an enantioselective synthesis of quaternary centres with novel ligands used to optimise the new system. Lastly, chapter five describes the extension of the method to some linear enones, using different ligands. Overall, we have developed a variety of ligands which were used to expand the enone scope of a conjugate addition and an understanding of what factors make these ligands effective.

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Palladium mediated allylic fluorination

Hollingworth, Charlotte

January 2013

In this thesis, the construction of the allylic fluorides under palladium catalysis was investigated. Chapter 1 provides a general introduction to organofluorine compounds and the use of palladium for the formation of both Csp²- and Csp³-F bonds. The aims of the thesis are presented. In Chapter 2 the identification that a p-nitrobenzoate is the optimum leaving group under Pd-catalysis to give allyl fluorides is described. A range of allylic fluorides was synthesized in 35->95% yield using the nucleophilic fluorinating reagent, TBAF(tBuOH)₄. To further develop this transformation we have examined the effect of a variety of leaving groups and phosphine ligands. This methodology led to the development of the first transition metal mediated C-¹⁸F bond formation. The development of Ir-catalysed fluorination of allylic carbonates to give allylic fluorides is also discussed. This system provided access to branched, E- and Z-linear allylic fluorides in a regioselective manner. This methodology was also translated to ¹⁸F radiochemistry. In Chapter 3 the synthesis of allylic fluorides via a C-H functionalisation with Pd and nucleophilic source of fluorine was investigated. Comprehensive screening of Pd sources, fluoride reagents and additives was performed. The presence of a quinone was found to be crucial for this transformation. Chapter 4 describes the synthesis and characterization of a series of allylpalladium(II) complexes and their subsequent reactivity towards a range of electrophilic fluorination reagents. Chapter 5 gives full experimental procedures and characterization data for all compounds.

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Imaging membrane potential

Wilkinson, James Daniel

January 2014

Imaging membrane potential is a promising technique in the elucidation of the interactions of large networks of neurons. The membrane potential in a neuron varies as an action potential, the basic electrical signal of neuronal communication, travels along the length of the cell. Voltage sensitive dyes play a key role by providing an optical readout of the electric field generated across a neuron membrane by the action potential. However, none of the dyes reviewed in Chapter 1 generate sufficient signal change with changes in membrane potential; this sensitivity problem limits the ability of the imaging membrane potential technique to allow the high spatial and temporal resolution necessary for neuronal networks to be better understood. This thesis features two avenues of research that are expected to result in the necessary enhancements to voltage sensitive dyes to improve the signal change. The first avenue is based on the effect of an electric field upon the non-linear optical properties of a porphyrin macromolecule. The encouraging field sensitivity of a previous porphyrin monomer voltage sensor inspired an investigation which identified optimisations to enhance the voltage sensitivity (Chapter 2). The design, synthesis and initial characterisation of optimised porphyrin voltage sensors is detailed in Chapter 3. The second avenue is based on the effect of an electric field upon the rate of intermolecular electron transfer. In a suitably designed dye, the competition between electron transfer and fluorescence, following excitation by incoming light, allows the fluorescence intensity to act as an optical indicator of the electron transfer rate. New dyes were rationally designed and synthesised, as this effect had not been applied to voltage sensitive imaging before the research detailed in Chapter 4. The challenging purification of the new amphiphilic dyes synthesised also inspired research into a novel testing method which does not require amphiphilic dyes (Chapter 5).

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