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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Towards Mosquitocides for Prevention of Vector-Borne Infectious Diseases : discovery and Development of Acetylcholinesterase 1 Inhibitors / Mot nya insekticider för bekämpning av sjukdomsbärande myggor : identifiering och utveckling av acetylkolinesteras 1 inhibitorer

Knutsson, Sofie

January 2016

Diseases such as malaria and dengue impose great economic burdens and are a serious threat to public health, with young children being among the worst affected. These diseases are transmitted by mosquitoes, also called disease vectors, which are able to transmit both parasitic and viral infections. One of the most important strategies in the battle against mosquito-borne diseases is vector control by insecticides and the goal is to prevent people from being bitten by mosquitoes. Today’s vector control methods are seriously threatened by the development and spread of insecticide-resistant mosquitos warranting the search for new insecticides. This thesis has investigated the possibilities of vector control using non-covalent inhibitors targeting acetylcholinesterase (AChE); an essential enzyme present in mosquitoes as well as in humans and other mammals. A key requirement for such compounds to be considered safe and suitable for development into new public health insecticides is selectivity towards the mosquito enzyme AChE1. The work presented here is focused on AChE1 from the disease transmitting mosquitoes Anopheles gambiae (AgAChE1) and Aedes aegypti (AaAChE1), and their human (hAChE) and mouse (mAChE) counterparts. By taking a medicinal chemistry approach and utilizing high throughput screening (HTS), new chemical starting points have been identified. Analysis of the combined results of three different HTS campaigns targeting AgAChE1, AaAChE1, and hAChE allowed the identification of several mosquito-selective inhibitors and a number of compound classes were selected for further development. These compounds are non-covalent inhibitors of AChE1 and thereby work via a different mechanism compared to current anti-cholinergic insecticides, whose activity is the result of a covalent modification of the enzyme. The potency and selectivity of two compound classes have been explored in depth using a combination of different tools including design, organic synthesis, biochemical assays, protein X-ray crystallography and homology modeling. Several potent inhibitors with promising selectivity for the mosquito enzymes have been identified and the insecticidal activity of one new compound has been confirmed by in vivo experiments on mosquitoes. The results presented here contribute to the field of public health insecticide discovery by demonstrating the potential of selectively targeting mosquito AChE1 using non-covalent inhibitors. Further, the presented compounds can be used as tools to study mechanisms important in insecticide development, such as exoskeleton penetration and other ADME processes in mosquitoes.

Mosquito

vector-borne diseases

vector control

insecticide

acetylcholinesterase

medicinal chemistry

high-throughput screening

organic synthesis

homology modeling

structure activity relationship

structure selectivity relationship