Discovery of a potent and highly selective PDK1 inhibitor via fragment-based drug discovery

We report the use of a fragment-based lead discovery method, Tethering with extenders, to discover a pyridinone fragment that binds in an adaptive site of the protein PDK1. With subsequent medicinal chemistry, this led to the discovery of a potent and highly selective inhibitor of PDK1, which binds in the ‘DFG-out’ conformation.     

Pharmacogenomics - it''s not just pharmacogenetics

New technologies in both combinatorial chemistry and combinatorial biology promise to unlock new opportunities for drug discovery and lead optimisation. Using such genome-based technologies to measure the dynamic properties of pharmacological systems, pharmacogenomics can now provide an objective measure of a drug's biological efficacy, including its potential adverse effects.     

Fragment-based drug discovery of carbonic anhydrase II inhibitors by dynamic combinatorial chemistry utilizing alkene cross metathesis

A fragment-based drug discovery approach to the synthesis and identification of small molecule inhibitors of bovine carbonic anhydrase II (bCA II) is described. The classical bCA II recognition fragment is an aromatic sulfonamide (ArSO2NH2) moiety. This fragment was incorporated into a scaffold building block, which was subsequently derivatized by dynamic combinatorial chemistry utilizing alkene cross metathesis as the reversible reaction. Screening against bCA II was then carried out and the results allowed determination of the relative bCA II binding affinities of the cross metathesis products that contained the ArSO2NH2 fragment. A bCA II competitive binding assay validated these results with a representative number of pure compounds. The results for screening, without prior isolation of the active constituent, were in full agreement with those obtained for equilibrium dissociation constants (K(i)'s) of pure compounds. Some of these compounds exhibited K(i)'s in the low nanomolar range. Heterogeneous catalysis was shown to be very effective in this drug discovery application of dynamic combinatorial chemistry.     

The inverse problems for some topological indices in combinatorial chemistry.

In the original paper, Goldman et al. (2000) launched the study of the inverse problems in combinatorial chemistry, which is closely related to the design of combinatorial libraries for drug discovery. Following their ideas, we investigate four other topological indices, i.e., the sigma-index, the c-index, the Z-index, and the M(1)-index, with a special emphasis on the sigma-index. Like the Wiener index, these four indices are very popular in combinatorial chemistry and reflect many chemical and physical properties. We give algorithmic and analytical solutions for the inverse problems of the four indices. We also show that the SUBTREEVALUE reconstruction problem for the sigma-index is NP-hard.     

Microfluidic combinatorial chemistry

Microreactors are finding increasing application in the field of combinatorial chemistry. In the past few years, microreactor chemistry has shown great promise as a novel method on which to build new chemical technology and processes. It has been conclusively demonstrated that reactions performed within microreactors invariably generate relatively pure products in high yield. One of the immediate and obvious applications is therefore in combinatorial chemistry and drug discovery.     

Mesofluidic devices for DNA-programmed combinatorial chemistry

Hybrid combinatorial chemistry strategies that use DNA as an information-carrying medium are proving to be powerful tools for molecular discovery. In order to extend these efforts, we present a highly parallel format for DNA-programmed chemical library synthesis. The new format uses a standard microwell plate footprint and is compatible with commercially available automation technology. It can accommodate a wide variety of combinatorial synthetic schemes with up to 384 different building blocks per chemical step. We demonstrate that fluidic routing of DNA populations in the highly parallel format occurs with excellent specificity, and that chemistry on DNA arrayed into 384 well plates proceeds robustly, two requirements for the high-fidelity translation and efficient in vitro evolution of small molecules.     

Solving chemical problems through the application of evolutionary principles

Molecular evolution has been widely applied in the laboratory to generate novel biological macromolecules. The principles underlying evolution have more recently been used to address problems in the chemical sciences, including the discovery of functional synthetic small molecules, catalysts, materials and new chemical reactions. The application of these principles in dynamic combinatorial chemistry and in efforts involving small molecule-nucleic acid conjugates has facilitated the evaluation of large numbers of candidate structures or reactions for desired characteristics. These early efforts suggest the promise of pairing evolutionary approaches with synthetic chemistry.     

Flow NMR applications in combinatorial chemistry

Flow NMR techniques are now well accepted and widely used in many areas of drug discovery. Although natural-product-, rational-drug-design-, and NMR-screening-programs have begun to use flow NMR more routinely, flow NMR has not yet gained widespread acceptance in combinatorial chemistry, even though it has been shown to be a potentially useful tool. Recent developments in DI-NMR, FIA-NMR, and LC-NMR will help flow NMR eventually gain a wider acceptance within combinatorial chemistry. These developments include LC-NMR-MS instrumentation, flow probe improvements, new pulse sequences, improved automation of NMR data analysis, and the application of flow NMR to related fields in drug discovery.     

Discovery of novel aspartyl ketone dipeptides as potent and selective caspase-3 inhibitors

The discovery of a series of potent, selective and reversible dipeptidyl caspase-3 inhibitors are reported. The iterative discovery process of using combinatorial chemistry, parallel synthesis, moleculare modelling and structural biology will be discussed.     

Computational Chemistry in Lead Identification,Library Design and Lead Optimisation

Abstract

We describe a variety of the computational techniques which we use in the drug discovery and design process. Some of these computational methods are designed to support the new experimental technologies of high-throughput screening and combinatorial chemistry. We also consider some new approaches to problems of long-standing interest such as protein-ligand docking and the prediction of free energies of binding.     

Inkjet dispensing technology: applications in drug discovery

The past year has seen significant advances in the reduction to practice of inkjet dispensing technology in drug discovery applications. Although much of the work in this area has been done by relatively few ‘early innovators’, broader acceptance of the feasibility of the use of inkjet dispensing is on the rise. Of the three main areas of drug discovery — genomics, high-throughput screening, and combinatorial chemistry — high-throughput screening has had the most applications to date. The burgeoning field of genomics has seen rapid incorporation of technologies that enable miniaturization of gene expression experiments. Inkjet dispensing has a clear role in this effort. Finally, as the miniaturization needs of combinatorial chemistry become more clear, inkjet dispensing technology will potentially play a role.     

Fragment-based discovery of potent inhibitors of the anti-apoptotic MCL-1 protein

Apoptosis is regulated by the BCL-2 family of proteins, which is comprised of both pro-death and pro-survival members. Evasion of apoptosis is a hallmark of malignant cells. One way in which cancer cells achieve this evasion is thru overexpression of the pro-survival members of the BCL-2 family. Overexpression of MCL-1, a pro-survival protein, has been shown to be a resistance factor for Navitoclax, a potent inhibitor of BCL-2 and BCL-XL. Here we describe the use of fragment screening methods and structural biology to drive the discovery of novel MCL-1 inhibitors from two distinct structural classes. Specifically, cores derived from a biphenyl sulfonamide and salicylic acid were uncovered in an NMR-based fragment screen and elaborated using high throughput analog synthesis. This culminated in the discovery of selective and potent inhibitors of MCL-1 that may serve as promising leads for medicinal chemistry optimization efforts.     

Chemical biology of dynamic combinatorial libraries

Dynamic combinatorial chemistry (DCC) is a recently introduced supramolecular approach to generate libraries of chemical compounds based on reversible exchange processes. The building elements are spontaneously and reversibly assembled to virtually encompass all possible combinations, allowing for simple one-step generation of complex libraries. The method has been applied to a variety of combinatorial systems, ranging from synthetic models to materials science and drug discovery, and enables the establishment of adaptive processes due to the dynamic interchange of the library constituents and its evolution toward the best fit to the target. In particular, it has the potential to become a useful tool in the direct screening of ligands to a chosen receptor without extensive prior knowledge of the site structure, and several biological systems have been targeted. In the vast field of glycoscience, the concept may find special perspective in response to the highly complex nature of carbohydrate-protein interactions. This chapter summarises studies that have been performed using DCC in biological systems, with special emphasis on glycoscience.     

The discovery of sulfonylated dipeptides as potent VLA-4 antagonists

Directed screening of a carboxylic acid-containing combinatorial library led to the discovery of potent inhibitors of the integrin VLA-4. Subsequent optimization by solid-phase synthesis afforded a series of sulfonylated dipeptide inhibitors with structural components that when combined in a single hybrid molecule gave a sub-nanomolar inhibitor as a lead for medicinal chemistry. Preliminary metabolic studies led to the discovery of substituted biphenyl derivatives with low picomolar activities. SAR and pharmacokinetic characterization of this series are presented.     

Combinatorial biocatalysis: taking the lead from nature

Combinatorial biocatalysis is an emerging technology in the field of drug discovery. The biocatalytic approach to combinatorial chemistry uses enzymatic, chemoenzymatic, and microbial transformations to generate libraries from lead compounds. Important recent advances in combinatorial biocatalysis include iterative derivatization of small molecules and complex natural products, regioselectively controlled libraries, novel one-pot library syntheses, process automation, and biocatalyst enhancements.     

A loop-mimetic inhibitor of the HCV-NS3 protease derived from a minibody

We have been interested for some time in establishing a strategy for deriving lead compounds from macromolecule ligands such as minibody variants. A minibody is a minimized antibody variable domain whose two loops are amenable to combinatorial mutagenesis. This approach can be especially useful when dealing with 'difficult' targets. One such target is the NS3 protease of hepatitis C virus (HCV), a human pathogen that is believed to infect about 100 million individuals worldwide and for which an effective therapy is not yet available. Based on known inhibitor specificity (residues P6-P1) of NS3 protease, we screened a number of minibodies from our collection and we were able to identify a competitive inhibitor of this enzyme. We thus validated an aspect of recognition by HCV NS3 protease, namely that an acid anchor is necessary for inhibitor activity. In addition, the characterization of the minibody inhibitor led to the synthesis of a constrained hexapeptide mimicking the bioactive loop of the parent macromolecule. The cyclic peptide is a lead compound prone to rapid optimization through solid phase combinatorial chemistry. We therefore confirmed that the potential of turning a protein ligand into a low molecular weight active compound for lead discovery is achievable and can complement more traditional drug discovery approaches.     

A solid-phase synthesis for beta-turn mimetics of sialyl Lewis X

A solid-phase synthesis of heterocyclic beta-turn mimetics of sialyl Lewis X, which is a natural carbohydrate ligand of selectins, was established. This synthetic method could be very useful for drug discovery of selectin antagonists using combinatorial chemistry techniques.     

Phosphinic peptide inhibitors as tools in the study of the function of zinc metallopeptidases

The development of the combinatorial chemistry of phosphinic peptides has led to the discovery of both highly potent and selective inhibitors of various zinc metalloproteinases. Several properties of these compounds are reviewed, supporting the view that this class of inhibitors should represent useful tools for probing several aspects of the function of this broad family of proteases in vivo.     

Combinatorial search for advanced luminescence materials.

Phosphors are key materials in fluorescent lighting, displays, x-ray scintillation, etc. The rapid development of modern photonic technologies, e.g., mercury-free lamps, flat panel displays, CT-detector array, etc., demands timely discovery of advanced phosphors. To this end, a combinatorial approach has been developed and applied to accelerated experimental search of advanced phosphors and scintillators. Phosphor libraries can be made in both thin film and powder form, using masking strategies and liquid dispensing systems, respectively. High-density libraries with 100 to 1000 discrete phosphor compositions on a 1"-square substrate can be made routinely. Both compositions and synthesis temperatures can be screened in a high-throughput mode. In this article, details on the existing methods of combinatorial synthesis and screening of phosphors will be reported with examples. These methods are generic tools for application of combinatorial chemistry in the discovery of other solid state materials. A few highly efficient phosphors discovered with combinatorial methods have been reproduced in bulk form and their luminescent properties measured.     

Discovery of novel Cyclophilin D inhibitors starting from three dimensional fragments with millimolar potencies

Fragment-based screening by SPR enabled the discovery of chemical diverse fragment hits with millimolar binding affinities to the peptidyl-prolyl isomerase Cyclophilin D (CypD). The CypD protein crystal structures of 6 fragment hits provided the basis for subsequent medicinal chemistry optimization by fragment merging and linking yielding three different chemical series with either urea, oxalyl or amide linkers connecting millimolar fragments in the S1′ and S2 pockets. We successfully improved the in vitro CypD potencies in the biochemical FP and PPIase assays and in the biophysical SPR binding assay from millimolar towards the low micromolar and submicromolar range by >1000-fold for some fragment derivatives. The initial SAR together with the protein crystal structures of our novel CypD inhibitors provide a suitable basis for further hit-to-lead optimization.