The Meisenheimer Complex as a Paradigm in Drug Discovery: Reversible Covalent Inhibition through C67 of the ATP Binding Site of PLK1.

The polo kinase family are important oncology targets that act in regulating entry into and progression through mitosis. Structure-guided discovery of a new class of inhibitors of Polo-like kinase 1 (PLK1) catalytic activity that interact with Cys67 of the ATP binding site is described. Compounds containing the benzothiazole N-oxide scaffold not only bind covalently to this residue, but are reversible inhibitors through the formation of Meisenheimer complexes. This mechanism of kinase inhibition results in compounds that can target PLK1 with high selectivity, while avoiding issues with irreversible covalent binding and interaction with other thiol-containing molecules in the cell. Due to renewed interest in covalent drugs and the plethora of potential drug targets, these represent prototypes for the design of kinase inhibitory compounds that achieve high specificity through covalent interaction and yet still bind reversibly to the ATP cleft, a strategy that could be applied to avoid issues with conventional covalent binders.

New 4-aryl-1,3,2-oxathiazolylium-5-olates: Chemical synthesis and photochemical stability of a novel series of S-nitrosothiols.

S-nitrosothiols (RSNOs) remain one of the most popular classes of NO-donating compounds due to their ability to release nitric oxide (NO) under non-enzymatic means whilst producing an inert disulphide by-product. However, alligning these compounds to the different biological fields of NO research has proved to be problematic due to the inherent instability of such compounds under a variety of conditions including heat, light and the presence of copper ions. 1,3,2-Oxathiazolylium-5-olates (OZOs) represent an interesting subclass of S-nitrosothiols that lock the -SNO moiety into a five membered heterocyclic ring in an attempt to improve the compound's overall stability. The synthesis of a novel series of halogen-containing OZOs was comprehensively studied resulting in a seven-step route and overall yields ranging between 21 and 37%. The photochemical stability of these compounds was assessed to determine if S-nitrosothiols locked within these mesoionic ring systems can offer greater stability and thereby release NO in a more controllable fashion than their non-cyclic counterparts.

Simulated drug discovery process to conduct a synoptic assessment of pharmacy students.

OBJECTIVE. To implement and assess a task-based learning exercise that prompts pharmacy students to integrate their understanding of different disciplines. DESIGN. Master of pharmacy (MPharm degree) students were provided with simulated information from several preclinical science and from clinical trials and asked to synthesize this into a marketing authorization application for a new drug. Students made a link to pharmacy practice by creating an advice leaflet for pharmacists. ASSESSMENT. Students' ability to integrate information from different disciplines was evaluated by oral examination. In 2 successive academic years, 96% and 82% of students demonstrated an integrated understanding of their proposed new drug. Students indicated in a survey that their understanding of the links between different subjects improved. CONCLUSION. Simulated drug discovery provides a learning environment that emphasizes the connectivity of the preclinical sciences with each other and the practice of pharmacy.

Synthesis and chemical characterisation of target identification reagents based on an inhibitor of human cell invasion by the parasite Toxoplasma gondii.

The use of phenotype-based screens as an approach for identifying novel small molecule tools is reliant on successful protein target identification strategies. Here we report on the synthesis and chemical characterisation of a novel reagent for protein target identification based on a small molecule inhibitor of human cell invasion by the parasite Toxoplasma gondii. A detailed (1)H NMR study and biological testing confirmed that incorporation of an amino-containing functional group into the aryl ring of this inhibitor was possible without loss of biological activity. Interesting chemical reactivity differences were identified resulting from incorporation of the new substituent. The amine functionality was then used to prepare a biotinylated reagent that is central to our current protein target identification studies with this inhibitor.

Probing structural effects on replication efficiency through comparative analyses of families of potential self-replicators.

A formidable synthetic apparatus for the creation of nanoscale molecular structures and supramolecular assemblies through molecular structures can potentially be created from systems that are capable of parallel automultiplication (self-replication). In order to achieve this goal, a detailed understanding of the relationship between molecular structure and replication efficiency is necessary. Diastereoisomeric templates that are capable of specific and simultaneous autocatalysis have been synthesised. A systematic experimental and theoretical evaluation of their behaviour and that of structurally-related systems reveals the key determinants that dictate the emergence of self-replicative function and defines the structural space within which this behaviour is observed.

Comparative analyses of a family of potential self-replicators: the subtle interplay between molecular structure and the efficacy of self-replication.

It is envisioned that protocols based on self-replication will emerge as a formidable synthetic apparatus for the production of nanoscale assemblies through molecular structures that are capable of automultiplication with high reaction rates and selectivities. To achieve this goal, a complete understanding of the relationship between molecular structure and replication efficiency is necessary. Rigorous experimental and theoretical analyses of a series of self-complementary scaffolds that are intimately related in a constitutional sense, manufactured through the Diels-Alder reaction of complementary subunits, were undertaken. Experimental and computational methods were employed to map the key determinants that dictate the emergence of self-replicative function, as well as the efficiency, rate and selectivity of the self-replicative processes.

Specific autocatalysis in diastereoisomeric replicators.

Two diastereoisomeric cycloadducts are capable of accelerating their own formation through the assembly of catalytic ternary complexes. The two cycloadducts do not have any measurable catalytic effect on the rate of formation of their diastereoisomer. [structure: see text]

Controlling the outcome of an N-alkylation reaction by using N-oxide functional groups.

Covalent modifiers of proteins are of importance in chemical proteomics, an emerging chemical technology used to assign protein function. In this study, high-field (1)H NMR techniques were used to analyze the reaction of the bioactive compound, 2,3-bis(bromomethyl)quinoxaline 1,4-dioxide, with amines (a model system for proteins containing nitrogen-based nucleophiles). Unexpectedly, the results show that a double nucleophilic substitution reaction involving 2 equiv of the amine is preferred to an intramolecular cyclization pathway. A direct comparison with the reaction carried out on a substrate lacking the N-oxide functional groups is also provided. X-ray crystal structures and computational studies are used to rationalize the observed differences in reactivity between the two systems.

Self-replication vs. reactive binary complexes--manipulating recognition-mediated cycloadditions by simple structural modifications.

The rate of reaction and the selectivity of a Diels-Alder cycloaddition between a furan and a maleimide can be enhanced by the introduction of complementary recognition sites on the reactant species. Subtle manipulation of other structural elements allows the generation of the observed rate enhancements and selectivities through either self-replication or formation of a pre-reactive binary complex.

Chemical synthesis and microvascular effects of new nitric oxide donors in humans.

Nitric oxide (NO) is produced continuously from the endothelium and plays a pivotal role in the control of vascular tone. Many of the current therapeutic agents that increase blood flow through production of NO have to be taken orally and can produce significant adverse side effects. We now report on some novel NO-donor drugs, based on thiosugars that generate NO spontaneously. From the range of compounds synthesized, D-SNAG ( S -nitroso-1-thio-2,3,4,6-tetra- O -acetyl-beta-D-glucopyranose) was as effective a vasodilator as any other and, as it was the easiest to synthesize, we undertook a more detailed evaluation to understand the chemistry and mode of action of its vasodilator effect. From the chemical kinetic data, we found that NO release occurred predominantly by thermal decomposition, with a 20-fold increase in decomposition rate between 19 and 37 degrees C. In the forearm of eight normal male subjects, we found that D-SNAG produced a significant dose-dependent vasodilator effect ( P =0.001) with good reproducibility (19%) on repeated testing. We propose that delivery of NO from D-SNAG to the forearm skin microvessels most probably occurs by diffusion across the epidermis. Since such compounds release NO in a non-enzymic manner following topical application, they might produce an attractive therapeutic source of localized NO delivery without inducing systemic side effects.