A single-step method for the production of sugar hydrazides: intermediates for the chemoselective preparation of glycoconjugates.

The ability to selectively conjugate carbohydrate molecules to a protein is a key step in the preparation of conjugate vaccines, while facile methods for linking carbohydrates to polymers or solid surfaces to produce diagnostic probes and functional microarrays are also sought. Here, we describe a simple, single-step method of producing glycosylhydrazides from unprotected sugars, which were then linked in a controlled manner to a desired carrier, through an appropriate linker. The method was chemoselective and did not require coupling reagents, and the native pyranose form of the reducing end residue was retained. Initially, mono- and disaccharide hydrazides were produced from the corresponding reducing sugars and linked to BSA through a bifunctional linker. Final exemplification of the procedure was demonstrated by the preparation of a LewisY tetrasaccharide protein conjugate, which was recognized by a LewisY monoclonal antibody indicating the preservation of the natural conformation of the tetrasaccharide in the final construct. It is envisaged that this method will have general applicability to a variety of functionally diverse reducing sugars and provide a route to highly defined glycoconjugates, without the need for elaborate synthetic strategies.

cis-6-oxo-hexahydro-2-oxa-1,4-diazapentalene and cis-6-oxo-hexahydropyrrolo[3,2-c]pyrazole based scaffolds: design rationale, synthesis and cysteinyl proteinase inhibition.

The 5,5-bicycles cis-6-oxo-hexahydro-2-oxa-1,4-diazapentalene 3 and cis-6-oxo-hexahydropyrrolo[3,2-c]pyrazole 4 were designed as rotationally restricted templates towards the preparation of inhibitors of CAC1 cysteinyl proteinases. The design strategy was exemplified through the solution and solid phase preparation of potent inhibitors of human cathepsin K and may potentially be applied to inhibitors of other CAC1 proteinases.

Synthesis and evaluation of cis-hexahydropyrrolo[3,2-b]pyrrol-3-one peptidomimetic inhibitors of CAC1 cysteinyl proteinases.

A stereoselective synthesis of functionalised cis-hexahydropyrrolo[3,2-b]pyrrol-3-ones has been developed through Fmoc and Cbz-protected intermediates 5 and 6. Building blocks 5 and 6 were prepared via the intramolecular cyclisation of anti-epoxide 17. The intramolecular reaction occurred exclusively through the anti-epoxide to provide the 5,5-cis-fused bicycle, whereas the syn-epoxide, which theoretically would provide the 5,5-trans-fused bicycle, remained unchanged. These experimental observations are consistent with a key design element that we have introduced within this novel bicyclic ketone scaffold. Our bicyclic design strategy provides chiral stability to the bridgehead stereocentre that is situated alpha to the ketone because the cis-fused geometry is both thermodynamically and kinetically stable. Building blocks 5 and 6 have been utilised in both solid phase and solution phase syntheses of peptidomimetics 22, 36-40, which exhibit potent in vitro inhibition against a range of CAC1 cysteinyl proteinases. Compound 22, a potent and selective inhibitor of human cathepsin K exhibited good primary DMPK properties along with promising activity in an in vitro cell-based human osteoclast assay of bone resorption.

Bicyclic peptidomimetic tetrahydrofuro[3,2-b]pyrrol-3-one and hexahydrofuro[3,2-b]pyridine-3-one based scaffolds: synthesis and cysteinyl proteinase inhibition.

A stereoselective synthesis of (3aS,6aR)-tetrahydrofuro[3,2-b]pyrrol-3-ones and (3aS,7aR)-hexahydrofuro[3,2-b]pyridine-3-ones has been developed through Fmoc protected scaffolds 12 and 13. A key design element within these novel bicyclic scaffolds, in particular the 5,5-fused system, was the inherent stability of the cis-fused geometry in comparison to that of the corresponding trans-fused. Since the bridgehead stereocentre situated beta to the ketone was of a fixed and stable configuration, the fact that cis ring fusion is both kinetically and thermodynamically stable with respect to trans ring fusion provides chiral stability to the bridgehead stereocentre that is situated alpha to the ketone. To exemplify this principle, building blocks 12 and 13 were designed, prepared and utilised in a solid phase combinatorial synthesis of peptidomimetic inhibitors 10, 45a-e, 11 and 46. Both series were chirally stable with 5,5-series 10 and 45a-e exhibiting potent in vitro activity against a range of CAC1 cysteinyl proteinases. Compound 10, a potent and selective inhibitor of cathepsin K, possessed good primary DMPK properties along with promising activity in an in vitro cell-based human osteoclast assay of bone resorption.

Novel chemoselective linkage chemistry toward controlled loading of ligands to proteins through in situ real-time quantification of conjugate formation.

'Linkage chemistry', which encompasses the science of chemical attachment of a ligand molecule to a carrier moiety, plays a crucial role in a wide range of biochemical and biophysical disciplines. In particular, the production of synthetic vaccines, where quality assurance criteria are an essential part of the approvals procedure for development of medicines, is reliant upon reproducible linkage chemistries. Herein, we describe novel 2-hydroxybenzaldehyde-based quaternary amine containing chemoselective linkers that provide a simple and robust linkage process that overcomes the deficiencies present in state-of-the-art linkage chemistries. The 2-hydroxybenzaldehyde groups undergo a pH-dependent absorbance change that enabled its nondestructive quantification, even when covalently attached to a wide range of proteins. Additionally, formation of a hydrazone bond between the benzaldehyde group and a range of ligand hydrazides resulted in a second reversible absorbance change enabling the forward (ligand loading) and reverse (ligand release for analysis) reactions of ligand-loaded proteins to be monitored in situ and quantified in real time. Incorporation of the quaternary amine moiety into our improved linkage chemistries was found to increase the relative solubility of protein conjugates and enabled significantly higher loading of proteins with linker and subsequent ligands, while retaining aqueous solubility, when compared to standard methods.

Functionalised 2,3-dimethyl-3-aminotetrahydrofuran-4-one and N-(3-oxo-hexahydrocyclopenta[b]furan-3a-yl)acylamide based scaffolds: synthesis and cysteinyl proteinase inhibition.

A stereoselective synthesis of functionalised (2R,3R)-2,3-dimethyl-3-amidotetrahydrofuran-4-one, its (2S,3R)-epimer and (3aR,6aR)-N-(3-oxo-hexahydrocyclopenta[b]furan-3a-yl)acylamide cysteinyl proteinase inhibitors has been developed using Fmoc-protected scaffolds 6-8 in a solid-phase combinatorial strategy. Within these scaffolds, the introduction of an alkyl substituent alpha to the ketone affords chiral stability to an otherwise configurationally labile molecule. Preparation of scaffolds 6-8 required stereoselective syntheses of suitably protected alpha-diazomethylketone intermediates 9-11, derived from appropriately protected alpha-methylthreonines (2R,3R)-12, (2R,3S)-13 and a protected analogue of (1R,2R)-1-amino-2-hydroxycyclopentanecarboxylic acid 14. Application of standard methods for the preparation of amino acid alpha-diazomethylketones, through treatment of the mixed anhydride or pre-formed acyl fluorides of intermediates 12-14 with diazomethane, proved troublesome giving complex mixtures. However, the desired alpha-diazomethylketones were isolated and following a lithium chloride/acetic acid promoted insertion reaction provided scaffolds 6-8. Elaboration of 6-8 on the solid phase gave alpha,beta-dimethyl monocyclic ketone based inhibitors 38a-f, 39a,b,d,e,f and bicyclic inhibitors 40a-e that exhibited low micromolar activity against a variety of cysteinyl proteinases.