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Synthesis of Dualsteric Ligands for Muscarinic Acetylcholine Receptors and Cholinesterase Inhibitors
(2017)
The study is dealing with the synthesis and pharmacological investigation of newly designed dualsteric ligands of muscarinic acetylcholine receptors belonging to the superfamily of G protein-coupled receptors. Such bipharmacophoric ligands combine the advantages of the orthosteric binding site (high-affinity) and of the topographically distinct allosteric binding site (subtype-selectivity) resulting in compounds with reduced side effects. This opens the way to a new therapeutic approach in the treatment of e.g. chronic pain, drug withdrawal, Parkinson`s and Alzheimer`s disease. Furthermore, the newly synthesized dualsteric compounds were pharmacologically investigated in order to get a better understanding of the activation and signaling processes in muscarinic acetylcholine receptors, especially with regard to partial agonism.
The development of the “dynamic ligand binding” concept offers new perspectives for ligand binding and signaling at G protein-coupled receptors. GPCRs are no longer considered as simple on/off switches. Dualsteric ligands can bind in a dualsteric pose, reflecting an active receptor state as well as in a purely allosteric binding pose, characterized by an inactive receptor state resulting in partial agonism. The degree of partial agonism depends on the ratio of active versus inactive receptor populations. On this basis, orthosteric/orthosteric hybrid ligands consisting of the antagonist atropine and scopolamine, respectively, as well as of the agonist iperoxo and isoxazole, respectively, linked via different alkyl chain length were synthesized in order to investigate partial agonism (Figure 1).
Figure 1: Structures of the synthesized iperoxo/isoxazole-atropine/scopolamine-hybrids.
Furthermore, different sets of quaternary and tertiary homodimers consisting either of two iperoxo or two acetylcholine units were synthesized in order to study their extent on partial agonism (Figure 2). The two agonists were connected by varying alkyl chain length. Binding studies on CHO-hM2 cells of the quaternary compounds revealed that dimerization of the agonist results in a loss of potency. The iperoxo-dimers reached higher maximum effects on the Gi- as well as on the Gs pathway in comparison to the acetylcholine-dimers. Besides the choice of the orthosteric building block (potency of the agonist), the alkyl chain length is also crucial for the degree of partial agonism.
Figure 2: Structures of the synthesized quat./tert. iperoxo/acetylcholine-homodimers.
Quinolone-based hybrids connected to the superagonist iperoxo and to the endogenous ligand acetylcholine, respectively, linked through an alkyl chain of different length were synthesized in order to develop further partial agonists (Figure 3). FRET studies confirmed M1 subtype-selectivity as well as linker dependent receptor response. The greatest positive FRET signal was observed with quinolone-C6-iper resulting from a positive cooperativity between the two separated moieties, alloster and orthoster. However, the corresponding hybrids with a longer linker led to an inverse FRET signal indicating a different binding mode, e.g. purely allosteric, in contrast to the shorter linked hybrids. Furthermore, the flexible alkyl spacer was replaced by a rigidified linker resulting in the hybrid quinolone-rigid-iperoxo (Figure 3). FRET studies on the M1 receptor showed reduced FRET kinetics, resulting from interactions between the bulky linker and the aromatic lid, located between the orthosteric and allosteric binding site. A bitopic binding mode of the rigidified hybrid is presumed. For further clarity, mutational studies are necessary.
Figure 3: M1-selective hybrid compounds.
Another aim of this work was the design and synthesis of new hybrid compounds, acting as agonists at the M1 and M2 receptor and as inhibitors for AChE and BChE in the context of M. Alzheimer. Several sets of hybrid compounds consisting of different pharmacophoric units (catalytic active site: phthalimide, naphthalimide, tacrine; peripheric anionic site: iperoxo, isoxazole) linked through a polymethylene chain of varying length were synthesized. Tac-C10-iper (Figure 4), consisting of tacrine and the superagonist iperoxo linked by a C10 polymethylene spacer, was found to have excellent anticholinesterase activity for both AChE (pIC50 = 9.81) and BChE (pIC50 = 8.75). Docking experiments provided a structural model to rationalize the inhibitory power towards AChE. Additionally, the tacrine related hybrids showed affinity to the M1 and M2 receptor. Such compounds, addressing more than one molecular target are favorable for multifactorial diseases such as Alzheimer.
Figure 4: Structure of the most active compound regarding anticholinesterase activity.
In summary, the choice of the pharmacophoric units, their connecting point as well as the nature, length, and flexibility of the linker play an important role for the activity of designed bivalent ligands. A shorter linker length cannot bridge both binding sites simultaneously in contrast to longer linker chains. On the other hand, too long linker chains can result in unwanted steric interactions. Further investigations with respect to structural variations of hybrid compounds, with or without quaternary ammonium groups, are necessary in the light of drug development.
GPCRs, particularly muscarinic receptors (mAChRs), are significant therapeutic targets in many physiological conditions. The significance of dualsteric hybrids selectively targeting mAChR subtypes is their great advantage in avoiding undesired side effects. This is attained by exploitation of the high affinity of ligand-binding to the orthosteric site and the structural diversity of the allosteric site to target an individual mAChR subtype, as well as offering signal bias to avoiding undesired transduction pathways. Furthermore, dualsteric targeting of mAChR subtypes helps in the elucidation of the physiological role of each individual mAChR subtype.
The first project was the attempt of synthesis of the M2-preferring ligand AFDX-384. AFDX-384 is known to preferentially bind to the M2 receptor subtype as an orthosteric antagonist, with partial interaction with residues in the allosteric site. This project aimed to re-trace the synthesis route of AFDX-384, to open the door to its upscaling and the future synthesis of AFDX-type dualsteric ligands. The multi-step synthesis of AFDX-384 is achieved through the synthesis of its 2 precursors, the chloro acyl derivative VIII and the piperidinyl derivative IV. Upscaled synthesis of the piperidinyl derivative IV was attained. Synthesis of the chloro acyl compound VIII was attempted. Several trials to synthesize the benzopyridodiazepine nucleus as well as its chloro-acylation resulted in the production of the novel crystal structures V and VI. X-ray crystallography was also done for crystallized molecules of the closed-ring benzopyridodiazepine VII that was previously synthesized. Chloro-acylation reactions of compound VII using phosgene seem to be attainable when done using reflux overnight. However, the use of methanol to aid in elution during silica gel column chromatography converted the expected product to the carbamate analogue IX. Hence, further attempts in purification should refrain from the use of methanol. The use of triphosgene instead of phosgene demonstrates a cleaner route for further upscaled synthesis.
The second project was the synthesis of dualsteric ligands involving variable orthosteric and allosteric moieties. Four different types of hybrids have been created over multiple steps. Dualsteric ligands have been synthesized using either a phthalimido- or 1,8-naphthalimidopropylamino moiety as the allosteric-binding group, coupled to either N-desmethyl pirenzepine or N-desmethyl clozapine using variable chain lengths. Furthermore, the synthesis of the dualsteric ligands involving N-desmethyl clozapine linked to either the super-agonist iperoxo or acetylcholine, and being connected using variable alkane chain lengths. Several reaction conditions have been investigated throughout the analysis of the optimal condition to conduct the critical final step of synthesis of these dualsteric hybrids, which involves the linking of the two segments of the hybrid together. The optimal method, which produced the least side products and highest yield, was to connect the two intermediates of the compound in absence of base, catalyst or microwaves while stirring at 35 °C for several days using acetonitrile as solvent (silica gel TLC monitoring, 0.2 M aqueous KNO3/MeOH 2:3). The ideal purification methods for the final compounds were found to be either crystallization from the reaction medium or using C18 reverse phase silica gel flash chromatography (using H2O/MeOH solvent system). All the hybrids will be subjected to pharmacological testing using the appropriate FRET assays.
The past decades have witnessed the development of new pharmaceutical compounds that modulate receptor function by targeting allosteric sites. Allosteric sites are, by definition, domains topographically distinct from the orthosteric binding pocket where the natural ligand binds. Exploring the possibilities of linking orthosteric and allosteric pharmacophores in one compound to yield ‘bitopic’ compounds is a strategy derived from the “message-address” concept by Schwyzer , first applied to GPCRs by Portoghese et al. This concept explicitly underlines the orthosteric/allosteric combination, in opposite to the more general umbrella term bivalent. The broad possibilities of bitopic ligands in the pharmaceutical field are under continuous study. Bitopic compounds are promising pharmaceutical tools for taking advantage of the allosteric binding to achieve subtype selectivity while preserving high affinity at the receptor. The development of bitopic ligands, based on the idea of combining high affinity (via orthosteric sites) with high selectivity (via allosteric sites), have led to the development of highly selective bivalent ligands for GPCRs , such as for the opioid receptors , muscarinic acetylcholine receptors (mAChRs), serotonin receptors, cannabinoid receptors, and gonadotropin-releasing hormone receptors. This concept has even been extended to other receptors, for examples nicotinic receptors and other proteins, such as acetylcholinesterases and the tyrosine kinase receptors TrkA and TrkC. The reasons to pursue a bitopic ligand approach are various. An improved affinity for the target GPCR and/or an improved selectivity either at the level of receptor subtype, or at the level of signaling pathway. Another advantage of bitopic ligands over purely allosteric ligands is that the former rely on the appropriate presence of endogenous agonist tone to mediate their effects, whereas a bitopic ligand would engage the orthosteric site irrespective of the presence or absence of endogenous tone. By way of introduction to the hybrid approach, a review of the concept of hybrids compounds targeting the cholinergic system is presented in section A of this thesis. Recent updates in hybrid molecule design as a strategy for selectively addressing multiple target proteins involved in Alzheimer's disease (AD) is here reported . This represents the potential and the growing interest in hybrid compound as pharmacological tools to achieve receptor subtype selectivity and/or, to study the overall functional activity of the receptor. Until now, muscarinic acetylcholine receptors (mAChRs) have proved to be a particularly fruitful receptor model for the development and characterization of bitopic ligands. In this thesis, several examples of new muscarinic bitopic approach are reported in the results section. A study of bipharmacophoric ligands composed of the muscarinic positive allosteric modulators (BQCAderived compounds) linked with chain of various lengths to different orthosteric building blocks is reported in the result part 1. Synthesis and examination of the potential pharmacological characteristic of Oxotremorine-BQCAd compounds and Xanomeline-BQCAd hybrid derivatives are described in results parts 2 and 4, respectively. Moreover, the bitopic concept has even been extended to other proteins, such as acetylcholinesterase. In the result part 5 an overview of the new Tacrine-Xanomeline hybrids aiming to improve the inhibitory potency of the acetylcholinesterase and simultaneously to increase the cholinergic tone, via the xanomelinic portion acting on the M1 receptor is given. A new trivalent approach is presented for the first time to deepen the study of the M1 muscarinic receptor in the result part 6. Moreover, the synthesis of a new series of iperoxo-derived alkane, bis(ammonio)alkane-type and rigidified chain ligands is given in the result part 7 together with some prospects for further research.
As part of the parasympathetic nervous system, muscarinic receptors are involved in the regulation of numerous functions in the human body. However, targeting a specific subtype of muscarinic receptors is challenging due to the high degree of similarity within the binding site of the endogenous neurotransmitter acetylcholine. Therefore, this study focused on the investigation of dualsteric ligands. Such hybrid ligands target the orthosteric acetylcholine binding site and, simultaneously, a distinct allosteric binding site. Since allosteric binding regions show significant structural differences throughout muscarinic receptor subtypes, it was aimed to produce selective ligands by means of combination of two pharmacophores in one molecule. Herein, the thienopyridine derivatives LY2033298 and LY2119620 were chosen as allosteric moieties. Based on literature studies, the investigated allosteric modulators were analyzed in terms of adequate attachment points for the combination with an orthosteric agonist. As orthosteric units, muscarinic superagonist iperoxo, xanomeline, and TMA were applied in this work. Since the distance between orthosteric and allosteric moieties plays a crucial role for dualsteric ligand binding, the linker chain length was also varied. Pharmacological investigations of the synthesized hybrid ligands were perfomed via FRET- and BRET-assay measurements.