Steve Courtney scite author profile

Representative diastereomeric, erythritol and threitol polyhydroxylated pyrrolidine imine scaffolds have been rapidly elaborated to diversely functionalized aza-sugars through highly diastereoselective organometallic (RM) additions (R=Me, Et, allyl, hexenyl, Ph, Bn, pMeO-Bn). The yields for these additions have all been substantially enhanced from previously optimised levels (<58 %) for normal additions using a reverse addition procedure (e.g. R=Ph; 44 % normal mode --> 78 % reverse mode). The high diastereoselectivities (>98 % de for all except R=Me) are consistent with additions that are controlled by the configuration of the C-2 centre adjacent to the azomethine imine carbon and the conformation of the pyrrolidine imine. The high potential of this method was demonstrated by concise syntheses of 1-epi- and 2-epi-desacetylanisomycins. In addition, the late stage addition of hydrophobic substituents, which this imine addition methodology allows, enabled the preparation of novel aza-sugars with enhanced inhibitory potential. This was highlighted by the screening of a representative selection of these "hydrophobically-modified" aza-sugars against a diverse panel of 12 non-mammalian and human carbohydrate-processing enzymes. This identified a novel nanomolar alpha-galactosidase inhibitor (IC(50)=250 nM) and a novel highly selective glucosylceramide synthase inhibitor (IC(50)=52 microM, no alpha-glucosidase inhibition at 1 mM). Furthermore, analysis of the structure-activity relationships of racemic series of inhibitors allowed some validation of Fleet's mirror-image enzyme active site postulate.

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The multiple roles of computational chemistry in fragment-based drug design

Law

Barker

et al. 2009

J Comput Aided Mol Des

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Fragment-based drug discovery (FBDD) represents a change in strategy from the screening of molecules with higher molecular weights and physical properties more akin to fully drug-like compounds, to the screening of smaller, less complex molecules. This is because it has been recognised that fragment hit molecules can be efficiently grown and optimised into leads, particularly after the binding mode to the target protein has been first determined by 3D structural elucidation, e.g. by NMR or X-ray crystallography. Several studies have shown that medicinal chemistry optimisation of an already drug-like hit or lead compound can result in a final compound with too high molecular weight and lipophilicity. The evolution of a lower molecular weight fragment hit therefore represents an attractive alternative approach to optimisation as it allows better control of compound properties. Computational chemistry can play an important role both prior to a fragment screen, in producing a target focussed fragment library, and post-screening in the evolution of a drug-like molecule from a fragment hit, both with and without the available fragment-target co-complex structure. We will review many of the current developments in the area and illustrate with some recent examples from successful FBDD discovery projects that we have conducted.

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Fragment screening by biochemical assay

Barker¹,

Courtney²,

Hesterkamp

et al. 2006

Expert Opinion on Drug Discovery

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The use of high concentration biochemical assays to identify weak binding fragment molecules can be an effective method to identify novel starting points for medicinal chemistry programmes. The combination of a high-quality fragment library with sensitive biochemical screening methods is a viable alternative to the more commonly used fragment screening methods such as nuclear magnetic resonance screening or high-throughput X-ray crystallography. Notably, there are a number of literature reports where fragment molecules have been identified by a high concentration biochemical assay. The use of high concentration screening of fragments using a portfolio of single-molecule fluorescence correlation spectroscopy detection techniques to ensure the highest reproducibility and sensitivity have been demonstrated, as well as the use of and X-ray crystallography to determine the binding mode of active fragments.

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Nitrogen Inversion as a Diastereomeric Relay in Azasugar Synthesis: The First Synthesis of Adenophorine

Maughan¹,

Davies²,

Claridge³

et al. 2003

Angew Chem Int Ed

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Novel Cyclic Sugar Imines: Carbohydrate Mimics and Easily Elaborated Scaffolds for Aza-Sugars

et al. 2001

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Steve Courtney

Highly Diastereoselective Additions to Polyhydroxylated Pyrrolidine Cyclic Imines: Ready Elaboration of Aza‐Sugar Scaffolds To Create Diverse Carbohydrate‐Processing Enzyme Probes

The multiple roles of computational chemistry in fragment-based drug design

Fragment screening by biochemical assay

Nitrogen Inversion as a Diastereomeric Relay in Azasugar Synthesis: The First Synthesis of Adenophorine

Novel Cyclic Sugar Imines: Carbohydrate Mimics and Easily Elaborated Scaffolds for Aza-Sugars

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