Exploring fragment space: Library construction, screening and fragment growing

Leurs, R. [Promotor]Esch, I.J.P. de [Copromotor

Fragment library design: efficiently hunting drugs in chemical space

With the growth in fragment-based drug discovery, numerous strategies have been described for the design of fragment libraries. Key choices need to be made on both the selection criteria to be applied and the source of the fragments in the library. Here we review some of the key trends and recent developments in the rapidly evolving field of fragment library design, providing an overview of current design strategies and surveying the characteristics of published fragment libraries. © 2010 Published by Elsevier Ltd

Interaction Kinetic and Structural Dynamic Analysis of Ligand Binding to Acetylcholine-Binding Protein

The mechanism of agonist interactions with Cys-loop ligand-gated ion channels has been studied using the acetylcholine-binding protein (AChBP) from Lymnaea stagnalis as a model protein and acetylcholine, nicotine, epibatidine, and a series of substituted quinuclidines as ligands. A biosensor-based assay for direct interaction studies of immobilized AChBP and small molecule ligands was developed. It allowed the characterization of the interaction kinetics of the ligands and the structural dynamics of the protein. The interactions with AChBP were very sensitive to variations in the experimental conditions and showed several types of complexities. These could be resolved into two types of ligand-induced secondary effects with different kinetics, representing fast and slow conformational changes. The data could be rationalized in a mechanistic model, and a structural interpretation of the interaction was obtained by molecular modeling involving induced fit and loop flexibility simulations. The data suggest that AChBP exhibits ligand-induced structural dynamics, as expected for the ligand gating mechanism of Cys-loop receptors. It shows that the formation of the initial encounter complex between AChBP and ligands is very rapid, in accordance with the functional characteristics required of neurotransmission. These developed procedures will enable further exploration of the mechanism of Cys-loop receptor function and the identification of specific ligands suitable for pharmacological use. © 2010 American Chemical Society

Triazole ligands reveal distinct molecular features that induce H4R affinity and subtly govern H4R/H3R selectivity

The histamine

Assembly of a π–π stack of ligands in the binding site of an acetylcholine-binding protein

Acetylcholine-binding protein is a water-soluble homologue of the extracellular ligand-binding domain of cys-loop receptors. It is used as a structurally accessible prototype for studying ligand binding to these pharmaceutically important pentameric ion channels, in particular to nicotinic acetylcholine receptors, due to conserved binding site residues present at the interface between two subunits. Here we report that an aromatic conjugated small molecule binds acetylcholine-binding protein in an ordered π-π stack of three identical molecules per binding site, two parallel and one antiparallel. Acetylcholine-binding protein stabilizes the assembly of the stack by aromatic contacts. Thanks to the plasticity of its ligand-binding site, acetylcholine-binding protein can accommodate the formation of aromatic stacks of different size by simple loop repositioning and minimal adjustment of the interactions. This type of supramolecular binding provides a novel paradigm in drug design. © 2013 Macmillan Publishers Limited. All rights reserved

Small and colorful stones make beautiful mosaics: Fragment-Based Chemogenomics

Smaller stones with a wide variety of colors make a higher resolution mosaic. In much the same way, smaller chemical entities that are structurally diverse are better able to interrogate protein binding sites. This feature article describes the construction of a diverse fragment library and an analysis of the screening of six representative protein targets belonging to three diverse target classes (G protein-coupled receptors ADRB2,

Surface Plasmon Resonance Biosensor Based Fragment Screening Using Acetylcholine Binding Protein Identifies Ligand Efficiency Hot Spots (LE Hot Spots) by Deconstruction of Nicotinic Acetylcholine Receptor alpha 7 Ligands

The soluble acetylcholine binding protein (AChBP) is a homologue of the ligand-binding domain of the nicotinic acetylcholine receptors (nAChR). To guide future fragment-screening using surface plasmon resonance (SPR) biosensor technology as a label-free, direct binding, biophysical screening assay, a focused fragment library was generated based on deconstruction of a set of α7 nAChR selective quinuclidine containing ligands with nanomolar affinities. The interaction characteristics of the fragments and the parent compounds with AChBP were evaluated using an SPR biosensor assay. The data obtained from this direct binding assay correlated well with data from the reference radioligand displacement assay. Ligand efficiencies for different (structural) groups of fragments in the library were correlated to binding with distinct regions of the binding pocket, thereby identifying ligand efficiency hot spots (LE hot spots). These hot spots can be used to identity the most promising hit fragments in a large scale fragment library screen. © 2010 American Chemical Society

Nanofractionation Spotter Technology for Rapid Contact less and High-Resolution Deposition of LC Eluent for Further Off-Line Analysis

The development of a contactless postcolumn spotter technology capable of rapidly and accurately depositing LC eluent onto another platform (e.g., 1536-well microtiter plates) is described. Many detection methodologies are suitable for online analysis, such as mass spectrometry, UV-vis, and fluorescence. In some cases, when online analysis is less suitable, off-line postcolumn analysis is the methodology of choice and usually relies on LC-based fractionation prior to detection (e.g., MALDI-MS, Raman spectrsocopy, biochemical assays). As fractionation generally involves loss in resolution, the technology described here allows high-resolution contactless fractionation by tailoring the fractionation frequency to the chromatographic peaks and mixing in of postcolumn reagents. Droplet ejection at frequencies of at least 6 Hz could be performed in the nanoliter to low microliter range with repeatabilities of ∼6%. Furthermore, multiple droplets can be ejected at the same position thereby allowing adjustment of fractionation volume and speed. The technology was evaluated, optimized, and validated prior to two proof-of-principle demonstrations comprising off-line chemical detection of injected fluorescein and off-line postcolumn biochemical detection of acetylcholine-binding protein ligands, both based on 1536-well plate reader analysis. © 2010 American Chemical Society