Lyn H. Jones

Squaramides: physical properties, synthesis and applications

Squaramides are remarkable four-membered ring systems derived from squaric acid that are able to form up to four hydrogen bonds. A high affinity for hydrogen bonding is driven through a concomitant increase in aromaticity of the ring. This hydrogen bonding and aromatic switching, in combination with structural rigidity, have been exploited in many of the applications of squaramides. Substituted squaramides can be accessed via modular synthesis under relatively mild or aqueous conditions, making them ideal units for bioconjugation and supramolecular chemistry. In this tutorial review the fundamental electronic and structural properties of squaramides are explored to rationalise the geometry, conformation, reactivity and biological activity.

Physicochemical drug properties associated with in vivo toxicological outcomes: a review

The genesis of any toxicological or safety outcome is multifactorial and complex; for this reason, it can be difficult for drug discovery projects to factor the avoidance of toxicity outcomes into their target design. A focus on readily measurable parameters from high-throughput in vitro assays (e.g., primary potency, clearance) is easier to handle and have become the mainstays of drug discovery projects. However, the fundamental origins of adverse safety or toxicity findings can be considered as deriving from four parameters, all of which are in the control of the drug designer. These can be described as primary pharmacology, off target pharmacology, the presence of a defined structural fragment that can be associated with adverse outcomes and the overall physicochemical properties of the molecule that may predispose it to adverse outcomes. In the drug discovery community, there has been recognition for many years of the influence of physicochemical drug properties (in particular lipophilicity) on the toxicology profile of compounds, and recent research is now beginning to quantify that risk in a probabilistic sense. This review focuses on the overall properties of classes of molecules that are associated with an increased probability of adverse outcomes in in vivo studies.

Small Molecules Targeting Hepatitis C Virus-Encoded NS5A Cause Subcellular Redistribution of Their Target: Insights into Compound Modes of Action

ABSTRACT The current standard of care for hepatitis C virus (HCV)-infected patients consists of lengthy treatment with interferon and ribavirin. To increase the effectiveness of HCV therapy, future regimens will incorporate multiple direct-acting antiviral (DAA) drugs. Recently, the HCV-encoded NS5A protein has emerged as a promising DAA target. Compounds targeting NS5A exhibit remarkable potency in vitro and demonstrate early clinical promise, suggesting that NS5A inhibitors could feature in future DAA combination therapies. Since the mechanisms through which these molecules operate are unknown, we have used NS5A inhibitors as tools to investigate their modes of action. Analysis of replicon-containing cells revealed dramatic phenotypic alterations in NS5A localization following treatment with NS5A inhibitors; NS5A was redistributed from the endoplasmic reticulum to lipid droplets. The NS5A relocalization did not occur in cells treated with other classes of HCV inhibitors, and NS5A-targeting molecules did not cause similar alterations in the localization of other HCV-encoded proteins. Time course analysis of the redistribution of NS5A revealed that the transfer of protein to lipid droplets was concomitant with the onset of inhibition, as judged by the kinetic profiles for these compounds. Furthermore, analysis of the kinetic profile of inhibition for a panel of test molecules permitted the separation of compounds into different kinetic classes based on their modes of action. Results from this approach suggested that NS5A inhibitors perturbed the function of new replication complexes, rather than acting on preformed complexes. Taken together, our data reveal novel biological consequences of NS5A inhibition, which may help enable the development of future assay platforms for the identification of new and/or different NS5A inhibitors.

Uptake, Efficacy, and Systemic Distribution of Naked, Inhaled Short Interfering RNA (siRNA) and Locked Nucleic Acid (LNA) Antisense

Antisense oligonucleotides (ASOs) and small interfering RNA (siRNA) promise specific correction of disease-causing gene expression. Therapeutic implementation, however, has been forestalled by poor delivery to the appropriate tissue, cell type, and subcellular compartment. Topical administration is considered to circumvent these issues. The availability of inhalation devices and unmet medical need in lung disease has focused efforts in this tissue. We report the development of a novel cell sorting method for quantitative, cell type-specific analysis of siRNA, and locked nucleic acid (LNA) ASO uptake and efficacy after intratracheal (i.t.) administration in mice. Through fluorescent dye labeling, we compare the utility of this approach to whole animal and whole tissue analysis, and examine the extent of tissue distribution. We detail rapid systemic access and renal clearance for both therapeutic classes and lack of efficacy at the protein level in lung macrophages, epithelia, or other cell types. We nevertheless observe efficient redirection of i.t. administered phosphorothioate (PS) LNA ASO to the liver and kidney leading to targeted gene knockdown. These data suggest delivery remains a key obstacle to topically administered, naked oligonucleotide efficacy in the lung and introduce inhalation as a potentially viable alternative to injection for antisense administration to the liver and kidneys.

Know your target, know your molecule

The pharmaceutical industry continues to experience significant attrition of drug candidates during phase 2 proof-of-concept clinical studies. We describe some questions about the characteristics of protein targets and small-molecule drugs that may be important to consider in drug-discovery projects and could improve prospects for future clinical success.

Novel Indazole Non-Nucleoside Reverse Transcriptase Inhibitors Using Molecular Hybridization Based on Crystallographic Overlays

A major problem associated with non-nucleoside reverse transcriptase inhibitors (NNRTIs) for the treatment of HIV is their lack of resilience to mutations in the reverse transcriptase (RT) enzyme. Using structural overlays of the known inhibitors efavirenz and capravirine complexed in RT as a starting point, and structure-based drug design techniques, we have created a novel series of indazole NNRTIs that possess excellent metabolic stability and mutant resilience.

Thermodynamic Optimisation in Drug Discovery: A Case Study Using Carbonic Anhydrase Inhibitors.

Historically the early stages of drug discovery have been based on finding the highest affinity compounds that bind to the target of interest, with little consideration for the forces driving the binding event. The association constant (Ka) can be defined by the equation DG = RTln Ka, with DG =DH TDS. To fully describe Ka it would therefore be beneficial to characterize both of the thermodynamic terms (DH and DS) that drive this affinity for binding. The importance of separating affinity into its thermodynamic components is emphasized by the ubiquitous “enthalpy/entropy compensation effect”, where large changes in DH and DS tend to be of similar but opposite signs and there is no net change in affinity, despite potentially very different binding mode. It has been proposed by Freire, and Ward & Holdgate that it is advantageous, in terms of both potency and selectivity, to start from an enthalpically-driven lead. It can also be argued that choosing compounds with different binding modes increases the variety of chemical substrate for optimization, therefore reducing the risk of all the compounds encountering the same side effects. These points emphasize the need to measure thermodynamic signatures of lead compounds as early in the drug discovery process as possible. The only method that directly measures the thermodynamics of a binding event in solution is isothermal titration calorimetry (ITC). Even though ITC can give a full thermodynamic signature (DGobs, DHobs, DSobs and KB, obs) from a single experiment, the full utilization of the technique for lead optimization has been hampered by technical limitations requiring substantial quantities of reagents. In addition, data have frequently been collected from optimized, but varied, experimental conditions for a particular system, and without appropriate controls the interpretation of results between studies is difficult. Here, we demonstrate that with recent advances in ITC technology and comparing subtly modified ligands against the same target, under identical conditions, and with X-ray data support, thermodynamic measurements can provide medicinal chemists with another differentiator in their quest to discover the best lead compounds. Moreover, these data are informative to medicinal chemists as they are applicable to situations where a less complete biophysical analysis is possible. We chose human carbonic anhydrase (hCA II) as a favorable system for this investigation as there is already a wealth of both 3D structures and calorimetric data available, which has established this protein as the leading model system. Additionally, the protein binds benzene sulfonamides (BSAs) with a 1:1 stoichiometry and does not undergo gross conformational changes upon binding, providing an essentially thermodynamically closed system that will therefore not complicate interpretation of the binding thermodynamics. The binding of BSA to hCA II is driven mainly through four H bonds from the sulfonamide, two H bonds to the Zn co-factor (which is itself coordinated by three histidine residues: His 94, His 96 and His 119) and two H bonds to Thr 199. The dominance of this sulfonamide interaction means that any changes in the thermodynamics of binding caused by additions to the benzene ring may be small and therefore requires careful experimental design. In addition, the effect that aryl substituents may have in terms of electron-withdrawing effects etc. on the sulfonamide binding must also be considered. ITC analysis was performed on seventeen benzene sulfonamide derivatives (1–17) and three benzylamide para-substituted benzene sulfonamides (18–20) by titration into hCA II. In

Selection of a Novel Anti-Nicotine Vaccine: Influence of Antigen Design on Antibody Function in Mice

Anti-nicotine vaccines may aid smoking cessation via the induction of anti-nicotine antibodies (Ab) which reduce nicotine entering the brain, and hence the associated reward. Ab function depends on both the quantity (titer) and the quality (affinity) of the Ab. Anti-nicotine vaccines tested previously in clinical studies had poor efficacy despite high Ab titer, and this may be due to inadequate function if Ab of low affinity were induced. In this study, we designed and synthesized a series of novel nicotine-like haptens which were all linked to diphtheria toxoid (DT) as carrier, but which differed in the site of attachment of linker to nicotine, the nature of linker used, and the handle used to attach the hapten to DT. The resulting hapten conjugates were evaluated in a mouse model, using CpG (a TLR9 agonist) and aluminum hydroxide (Al(OH)3) as adjuvants, whereby Ab titers, affinity and function were evaluated using a radiolabeled nicotine challenge model. A series of additional linkers varying in length, rigidity and polarity were used with a single hapten to generate additional DT-conjugates, which were also tested in mice. Conjugates made with different haptens resulted in various titers of anti-nicotine Ab. Several haptens gave similarly high Ab titers, but among these, Ab affinity and hence function varied considerably. Linker also influenced Ab titer, affinity and function. These results demonstrate that immune responses induced in mice by nicotine-conjugate antigens are greatly influenced by hapten design including site of attachment of linker to nicotine, the nature of linker used, and the handle used to attach the hapten to DT. While both Ab titer and affinity contributed to function, affinity was more sensitive to antigen differences.

Rational Targeting of Active-Site Tyrosine Residues Using Sulfonyl Fluoride Probes

This work describes the first rational targeting of tyrosine residues in a protein binding site by small-molecule covalent probes. Specific tyrosine residues in the active site of the mRNA-decapping scavenger enzyme DcpS were modified using reactive sulfonyl fluoride covalent inhibitors. Structure-based molecular design was used to create an alkyne-tagged probe bearing the sulfonyl fluoride warhead, thus enabling the efficient capture of the protein from a complex proteome. Use of the probe in competition experiments with a diaminoquinazoline DcpS inhibitor permitted the quantification of intracellular target occupancy. As a result, diaminoquinazoline upregulators of survival motor neuron protein that are used for the treatment of spinal muscular atrophy were confirmed as inhibitors of DcpS in human primary cells. This work illustrates the utility of sulfonyl fluoride probes designed to react with specific tyrosine residues of a protein and augments the chemical biology toolkit by these probes uses in target validation and molecular pharmacology.

Applications of chemogenomic library screening in drug discovery

The allure of phenotypic screening, combined with the industry preference for target-based approaches, has prompted the development of innovative chemical biology technologies that facilitate the identification of new therapeutic targets for accelerated drug discovery. A chemogenomic library is a collection of selective small-molecule pharmacological agents, and a hit from such a set in a phenotypic screen suggests that the annotated target or targets of that pharmacological agent may be involved in perturbing the observable phenotype. In this Review, we describe opportunities for chemogenomic screening to considerably expedite the conversion of phenotypic screening projects into target-based drug discovery approaches. Other applications are explored, including drug repositioning, predictive toxicology and the discovery of novel pharmacological modalities.