Synthesis, Biological Evaluation, and Docking Studies of Antagonistic Hydroxylated Arecaidine Esters Targeting mAChRs.
Jonas KilianMarlon MillardMarius OzenilDominik KrauseKhadija GhaderiWolfgang HolzerErnst UrbanHelmut SpreitzerWolfgang WadsakMarcus HackerThierry LangerVerena PichlerPublished in: Molecules (Basel, Switzerland) (2022)
The muscarinic acetylcholine receptor family is a highly sought-after target in drug and molecular imaging discovery efforts aimed at neurological disorders. Hampered by the structural similarity of the five subtypes' orthosteric binding pockets, these efforts largely failed to deliver subtype-selective ligands. Building on our recent successes with arecaidine-derived ligands targeting M 1 , herein we report the synthesis of a related series of 11 hydroxylated arecaidine esters. Their physicochemical property profiles, expressed in terms of their computationally calculated CNS MPO scores and HPLC-logD values, point towards blood-brain barrier permeability. By means of a competitive radioligand binding assay, the binding affinity values towards each of the individual human mAChR subtypes h M 1 - h M 5 were determined. The most promising compound of this series 17b was shown to have a binding constant towards h M 1 in the single-digit nanomolar region (5.5 nM). Similar to our previously reported arecaidine-derived esters, the entire series was shown to act as h M1R antagonists in a calcium flux assay. Overall, this study greatly expanded our understanding of this recurring scaffolds' structure-activity relationship and will guide the development towards highly selective mAChRs ligands.
Keyphrases
- blood brain barrier
- high throughput
- endothelial cells
- binding protein
- dna binding
- structure activity relationship
- cerebral ischemia
- cancer therapy
- ms ms
- small molecule
- quality improvement
- molecular dynamics simulations
- simultaneous determination
- mass spectrometry
- single cell
- high performance liquid chromatography
- electronic health record
- subarachnoid hemorrhage