Abstract
Acetylcholinesterase (AChE) is an essential enzyme that terminates cholinergic transmission by rapid hydrolysis of the neurotransmitter acetylcholine. Compounds inhibiting this enzyme can be used (inter alia) to treat cholinergic deficiencies (e.g. in Alzheimer's disease), but may also act as dangerous toxins (e.g. nerve agents such as sarin). Treatment of nerve agent poisoning involves use of antidotes, small molecules capable of reactivating AChE. We have screened a collection of organic molecules to assess their ability to inhibit the enzymatic activity of AChE, aiming to find lead compounds for further optimization leading to drugs with increased efficacy and/or decreased side effects. 124 inhibitors were discovered, with considerable chemical diversity regarding size, polarity, flexibility and charge distribution. An extensive structure determination campaign resulted in a set of crystal structures of protein-ligand complexes. Overall, the ligands have substantial interactions with the peripheral anionic site of AChE, and the majority form additional interactions with the catalytic site (CAS). Reproduction of the bioactive conformation of six of the ligands using molecular docking simulations required modification of the default parameter settings of the docking software. The results show that docking-assisted structure-based design of AChE inhibitors is challenging and requires crystallographic support to obtain reliable results, at least with currently available software. The complex formed between C5685 and Mus musculus AChE (C5685•mAChE) is a representative structure for the general binding mode of the determined structures. The CAS binding part of C5685 could not be structurally determined due to a disordered electron density map and the developed docking protocol was used to predict the binding modes of this part of the molecule. We believe that chemical modifications of our discovered inhibitors, biochemical and biophysical characterization, crystallography and computational chemistry provide a route to novel AChE inhibitors and reactivators.
Highlights
The cholinergic system controls signals from nerve cells to muscle cells or other nerve cells and is essential in all higher organisms
The crystal structure of AChE shows that the catalytic triad, which is formed by serine, histidine and glutamate, is located at the bottom of a narrow 20-A -deep gorge that penetrates halfway into the enzyme and widens close to its base [2,3]
A similar interaction pattern can be seen at the catalytic site (CAS), and it is believed that ACh initially binds to the peripheral anionic site (PAS) and rapidly diffuses down to the catalytic site [1,2]
Summary
The cholinergic system controls signals from nerve cells to muscle cells or other nerve cells and is essential in all higher organisms. The crystal structure of AChE shows that the catalytic triad, which is formed by serine, histidine and glutamate, is located at the bottom of a narrow 20-A -deep gorge that penetrates halfway into the enzyme and widens close to its base [2,3]. The entrance of the gorge is termed the peripheral anionic site (PAS) as it was initially believed to contain several negatively charged amino acids due to its preference of binding cationic ligands [4]. The crystal structure indicates that insufficient acidic amino acids are located close to the ligand-binding cavity to support this hypothesis. Instead it has been shown that aromatic residues interact with cationic ligands [2,5]. A similar interaction pattern can be seen at the catalytic site (CAS), and it is believed that ACh initially binds to the PAS and rapidly diffuses down to the catalytic site [1,2]
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