Development of 3‐Phenyl‐N‐(2‐(3‐phenylureido)ethyl)‐thiophene‐2‐sulfonamide Compounds as Inhibitors of Antiapoptotic Bcl‐2 Family Proteins

Antiapoptotic Bcl‐2 family proteins, such as Bcl‐x_L, Bcl‐2, and Mcl‐1, are often overexpressed in tumor cells, which contributes to tumor cell resistance to chemotherapies and radiotherapies. Inhibitors of these proteins thus have potential applications in cancer treatment. We discovered, through structure‐based virtual screening, a lead compound with micromolar binding affinity to Mcl‐1 (inhibition constant (K_i)=3 μM ). It contains a phenyltetrazole and a hydrazinecarbothioamide moiety, and it represents a structural scaffold not observed among known Bcl‐2 inhibitors. This work presents the structural optimization of this lead compound. By following the scaffold‐hopping strategy, we have designed and synthesized a total of 82 compounds in three sets. All of the compounds were evaluated in a fluorescence‐polarization binding assay to measure their binding affinities to Bcl‐x_L, Bcl‐2, and Mcl‐1. Some of the compounds with a 3‐phenylthiophene‐2‐sulfonamide core moiety showed sub‐micromolar binding affinities to Mcl‐1 (K_i=0.3–0.4 μM ) or Bcl‐2 (K_i≈1 μM ). They also showed obvious cytotoxicity on tumor cells (IC₅₀<10 μM ). Two‐dimensional heteronuclear single quantum coherence NMR spectra of three selected compounds, that is, YCW‐E5, YCW‐E10, and YCW‐E11, indicated that they bind to the BH3‐binding groove on Bcl‐x_L in a similar mode to ABT‐737. Several apoptotic assays conducted on HL‐60 cells demonstrated that these compounds are able to induce cell apoptosis through the mitochondrial pathway. We propose that the compounds with the 3‐phenylthiophene‐2‐sulfonamide core moiety are worth further optimization as effective apoptosis inducers with an interesting selectivity towards Mcl‐1 and Bcl‐2.     

Design,Synthesis, in vitro MAO‐B Inhibitory Evaluation,and Computational Studies of Some 6‐Nitrobenzothiazole‐Derived Semicarbazones

Monoamine oxidase B (MAO‐B) is an important drug target for the treatment of neurological disorders. A series of 6‐nitrobenzothiazole‐derived semicarbazones were designed, synthesized, and evaluated as inhibitors of the rat brain MAO‐B isoenzyme. Most of the compounds were found to be potent inhibitors of MAO‐B, with IC₅₀ values in the nanomolar to micromolar range. Molecular docking studies were performed with AutoDock 4.2 to deduce the affinity and binding mode of these inhibitors toward the MAO‐B active site. The free energies of binding (ΔG) and inhibition constants (K_i) of the docked compounds were calculated by the Lamarckian genetic algorithm (LGA) of AutoDock 4.2. Good correlations between the calculated and experimental results were obtained. 1‐[(4‐Chlorophenyl)(phenyl)methylene]‐4‐(6‐nitrobenzothiazol‐2‐yl)semicarbazide emerged as the lead MAO‐B inhibitor, with top ranking in both the experimental MAO‐B assay (IC₅₀: 0.004±0.001 μM ) and in computational docking studies (K_i: 1.08 μM ). Binding mode analysis of potent inhibitors suggests that these compounds are well accommodated by the MAO‐B active site through stable hydrophobic and hydrogen bonding interactions. Interestingly, the 6‐nitrobenzothiazole moiety is stabilized in the substrate cavity with the aryl or diaryl residues extending up into the entrance cavity of the active site. According to our results, docking experiments could be an interesting approach for predicting the activity and binding interactions of this class of semicarbazones against MAO‐B. Thus, a binding site model consisting of three essential pharmacophoric features is proposed, and this can be used for the design of future MAO‐B inhibitors.     

N‐Benzyl Substitution of Polyhydroxypyrrolidines: The Way to Selective Inhibitors of Golgi α‐Mannosidase II

Inhibition of the biosynthesis of complex N‐glycans in the Golgi apparatus influences progress of tumor growth and metastasis. Golgi α‐mannosidase II (GMII) has become a therapeutic target for drugs with anticancer activities. One critical task for successful application of GMII drugs in medical treatments is to decrease their unwanted co‐inhibition of lysosomal α‐mannosidase (LMan), a weakness of all known potent GMII inhibitors. A series of novel N‐substituted polyhydroxypyrrolidines was synthesized and tested with modeled GH38 α‐mannosidases from Drosophila melanogaster (GMIIb and LManII). The most potent structures inhibited GMIIb (K_i=50–76 μm , as determined by enzyme assays) with a significant selectivity index of IC₅₀(LManII)/IC₅₀(GMIIb) >100. These compounds also showed inhibitory activities in in vitro assays with cancer cell lines (leukemia, IC₅₀=92–200 μm ) and low cytotoxic activities in normal fibroblast cell lines (IC₅₀>200 μm ). In addition, they did not show any significant inhibitory activity toward GH47 Aspergillus saitoiα1,2‐mannosidase. An appropriate stereo configuration of hydroxymethyl and benzyl functional groups on the pyrrolidine ring of the inhibitor may lead to an inhibitor with the required selectivity for the active site of a target α‐mannosidase.     

Probing the Peptidylglycine α‐Hydroxylating Monooxygenase Active Site with Novel 4‐Phenyl‐3‐butenoic Acid Based Inhibitors

Specific inhibition of the copper‐containing peptidylglycine α‐hydroxylating monooxygenase (PHM), which catalyzes the post‐translational modification of peptides involved in carcinogenesis and tumor progression, constitutes a new approach for combating cancer. We carried out a structure–activity study of new compounds derived from a well‐known PHM substrate analogue, the olefinic compound 4‐phenyl‐3‐butenoic acid (PBA). We designed, synthesized, and tested various PBA derivatives both in vitro and in silico. We show that it is possible to increase PBA affinity for PHM by appropriate functionalization of its aromatic nucleus. Compound 2 d , for example, bears a meta‐benzyloxy substituent, and exhibits better inhibition features (K_i=3.9 μM , k_inact/K_i=427 M ^?1 s^?1) than the parent PBA (K_i=19 μM , k_inact/K_i=82 M ^?1 s^?1). Docking calculations also suggest two different binding modes for PBA derivatives; these results will aid in the development of further PHM inhibitors with improved features.     

Small-Molecule Inhibitors Targeting Sterol 14α-Demethylase (CYP51): Synthesis,Molecular Modelling and Evaluation Against Candida albicans

Fungal infections are a global issue affecting over 150 million people worldwide annually, with 750 000 of these caused by invasive Candida infections. Azole drugs are the frontline treatment against fungal infections; however, resistance to current azole antifungals in C. albicans poses a threat to public health. Two series of novel azole derivatives, short and extended derivatives, have been designed, synthesised and investigated for CYP51 inhibitory activity, binding affinity and minimum inhibitory concentration (MIC) against C. albicans strains. The short derivatives were more potent against the C. albicans strains (e. g., MIC 2-(4-chlorophenyl)-N-(2,4-dichlorobenzyl)-3-(1H-imidazol-1-yl)propanamide ( 5 f ) <0.03 μg/mL, N-(4-((4-chlorophenyl)sulfonamido)benzyl)-2-phenyl-3-(1H-1,2,4-triazol-1-yl)propanamide ( 12 c ), 1 μg/mL, fluconazole 0.125 μg/mL) but both displayed comparable enzyme binding and inhibition ( 5 f K_d 62±17 nM, IC₅₀ 0.46 μM; 12 c K_d 43±18 nM, IC₅₀ 0.33 μM, fluconazole K_d 41±13 nM, IC₅₀ 0.31 μM, posaconazole K_d 43±11 nM, IC₅₀ 0.2 μM). The short series had poor selectivity for CaCYP51 over the human homologue, whereas the selectivity of the extended series, for example, compound 12 c , was higher (21.5-fold) than posaconazole (4.7-fold) based on K_d values, although posaconazole was more selective (615-fold) than 12 c (461-fold) based on IC₅₀ values. Based on inhibitory activity and selectivity profile, the extended series are the better of the two series for further development.     

Discovery of 3‐Hydroxy‐3‐phenacyloxindole Analogues of Isatin as Potential Monoamine Oxidase Inhibitors

A series of 3‐hydroxy‐3‐phenacyloxindole analogues of isatin were designed, synthesized, and evaluated in vitro for their inhibitory activity toward monoamine oxidase (MAO) A and B. Most of the synthesized compounds proved to be potent and selective inhibitors of MAO‐A rather than MAO‐B. 1‐Benzyl‐3‐hydroxy‐3‐(4′‐hydroxyphenacyl)oxindole (compound 18 ) showed the highest MAO‐A inhibitory activity (IC₅₀: 0.009±0.001 μm , K_i: 3.69±0.003 nm ) and good selectivity (selectivity index: 60.44). Kinetic studies revealed that compounds 18 and 16 (1‐benzyl‐3‐hydroxy‐3‐(4′‐bromophenacyl)oxindole) exhibit competitive inhibition against MAO‐A and MAO‐B, respectively. Structure–activity relationship studies suggested that the 3‐hydroxy group is an essential feature for these analogues to exhibit potent MAO‐A inhibitory activity. Computational studies revealed the possible molecular interactions between the inhibitors and MAO isozymes. The computational data obtained are congruent with experimental results. Further studies on the lead inhibitors, including co‐crystallization of inhibitor–MAO complexes and in vivo evaluations, are essential for their development as potential therapeutic agents for the treatment of MAO‐associated neurological disorders.     

Iminodiacetic Acid as a Novel Metal-Binding Pharmacophore for New Delhi Metallo-β-lactamase Inhibitor Development

The fungal natural product aspergillomarasmine A (AMA) has been identified as a noncompetitive inhibitor of New Delhi metallo-β-lactamase-1 (NDM-1) that inhibits by removing Zn^II from the active-site. The nonselective metal-chelating properties and difficult synthesis and derivatization of AMA have hindered the development of this scaffold into a potent and selective inhibitor of NDM-1. Iminodiacetic acid (IDA) has been identified as the metal-binding pharmacophore (MBP) core of AMA that can be leveraged for inhibitor development. Herein, we report the use of IDA for fragment-based drug discovery (FBDD) of NDM-1 inhibitors. IDA (IC₅₀=120 μM) was developed into inhibitor 23 f (IC₅₀=8.6 μM, K_i=2.6 μM), which formed a ternary complex with NDM-1, as evidenced by protein thermal-shift and native-state electrospray ionization mass spectrometry (ESI-MS) experiments. Combining mechanistic analysis with inhibitor derivatization, the use of IDA as an alternative AMA scaffold for NDM-1 inhibitor development is detailed.     

Development of Rhodesain Inhibitors with a 3‐Bromoisoxazoline Warhead

Novel rhodesain inhibitors were obtained by combining an enantiomerically pure 3‐bromoisoxazoline warhead with a specific peptidomimetic recognition moiety. All derivatives behaved as inhibitors of rhodesain, with low micromolar K_i values. Their activity against the enzyme was found to be paralleled by an in vitro antitrypanosomal activity, with IC₅₀ values in the mid‐micromolar range. Notably, a preference for parasitic over human proteases, specifically cathepsins B and L, was observed.     

Monoamine Oxidase (MAO) Inhibitory Activity: 3‐Phenylcoumarins versus 4‐Hydroxy‐3‐phenylcoumarins

Monoamine oxidase (MAO) is a useful target in the treatment of neurodegenerative diseases and depressive disorders. Both isoforms, MAO‐A and MAO‐B, are known to play critical roles in disease progression, and as such, the identification of novel, potent and selective inhibitors is an important research goal. Here, two series of 3‐phenylcoumarin derivatives were synthesized and evaluated against MAO‐A and MAO‐B. Most of the compounds tested acted preferentially on MAO‐B, with IC₅₀ values in the micromolar to nanomolar range. Only 6‐chloro‐4‐hydroxy‐3‐(2’‐hydroxyphenyl)coumarin exhibited activity against the MAO‐A isoform, while still retaining good selectivity for MAO‐B. 6‐Chloro‐3‐phenylcoumarins unsubstituted at the 4 position were found to be more active as MAO‐B inhibitors than the corresponding 4‐hydroxylated coumarins. For 4‐unsubstituted coumarins, meta and para positions on the 3‐phenyl ring seem to be the most favorable for substitution. Molecular docking simulations were used to explain the observed hMAO‐B structure–activity relationships for this type of compound. 6‐Chloro‐3‐(3’‐methoxyphenyl)coumarin was the most active compound identified (IC₅₀=0.001 μM ) and is several times more potent and selective than the reference compound, R‐(?)‐deprenyl hydrochloride. This compound represents a novel tool for the further investigation of the therapeutic potential of MAO‐B inhibitors.     

Discovery, structure-activity relationship studies, and crystal structure of nonpeptide inhibitors bound to the Shank3 PDZ domain

Shank is the central scaffolding protein of the postsynaptic density (PSD) protein complex found in cells of the central nervous system. Cellular studies indicate a prominent role of the protein in the organization of the PSD, in the development of neuronal morphology, in neuronal signaling, and in synaptic plasticity, thus linking Shank functions to the molecular basis of learning and memory. Mutations in the Shank gene have been found in several neuronal disorders including mental retardation, typical autism, and Asperger syndrome. Shank is linked to the PSD complex via its PDZ domain that binds to the C‐terminus of guanylate‐kinase‐associated protein (GKAP). Here, small‐molecule inhibitors of Shank3 PDZ domain are developed. A fluorescence polarization assay based on an identified high‐affinity peptide is established, and tetrahydroquinoline carboxylates are identified as inhibitors of this protein–protein interaction. Chemical synthesis via a hetero‐Diels–Alder strategy is employed for hit optimization, and structure–activity relationship studies are performed. Best hits possess K_i values in the 10 μM range, and binding to the PDZ domain is confirmed by ¹H,¹⁵N HSQC NMR experiments. One of the hits crystallizes with the Shank3 PDZ domain. The structure, analyzed at a resolution of 1.85 Å, reveals details of the binding mode. Finally, binding to PDZ domains of PSD‐95, syntrophin, and DVL3 was studied using ¹H,¹⁵N HSQC NMR spectroscopy.     

Discovery of a Small‐Molecule pBcl‐2 Inhibitor that Overcomes pBcl‐2‐Mediated Resistance to Apoptosis

Although the role of Bcl‐2 phosphorylation is still under debate, it has been identified in a resistance mechanism to BH3 mimetics, for example ABT‐737 and S1 . We identified an S1 analogue, S1‐16 , as a small‐molecule inhibitor of pBcl‐2. S1‐16 efficiently kills EEE‐Bcl‐2 (a T69E, S70E, and S87E mutant mimicking phosphorylation)‐expressing HL‐60 cells and high endogenously expressing pBcl‐2 cells, by disrupting EEE‐Bcl‐2 or native pBcl‐2 interactions with Bax and Bak, followed by apoptosis. In vitro binding assays showed that S1‐16 binds to the BH3 binding groove of EEE‐Bcl‐2 (K_d=0.38 μM by ITC; IC₅₀=0.16 μM by ELISA), as well as nonphosphorylated Bcl‐2 (npBcl‐2; K_d=0.38 μM ; IC₅₀=0.12 μM ). However, ABT‐737 and S1 had much weaker affinities to EEE‐Bcl‐2 (IC₅₀=1.43 and >10 μM , respectively), compared with npBcl‐2 (IC₅₀=0.011 and 0.74 μM , respectively). The allosteric effect on BH3 binding groove by Bcl‐2 phosphorylation in the loop region was illustrated for the first time.     

Discovery of a competitive apelin receptor (APJ) antagonist

The apelin receptor (APJ) is a class A G‐protein‐coupled receptor (GPCR) and is a putative target for the treatment of cardiovascular and metabolic diseases. Apelin‐13 (NH₂‐QRPRLSHKGPMPF‐COOH) is a vasoactive peptide and one of the most potent endogenous inotropic agents identified to date. We report the design and discovery of a novel APJ antagonist. By using a bivalent ligand approach, we have designed compounds with two ′affinity′ motifs and a short series of linker groups with different conformational and non‐bonded interaction properties. One of these, cyclo(1–6)CRPRLC‐KH‐cyclo(9–14)CRPRLC is a competitive antagonist at APJ. Radioligand binding in CHO cells transfected with human APJ gave a K_i value of 82 nM , competition binding in human left ventricle gave a K_D value of 3.2 μM , and cAMP accumulation assays in CHO‐K1‐APJ cells gave a K_D value of 1.32 μM .     

Synthesis and Evaluation of New Antagonists of Bacterial Quorum Sensing in Vibrio harveyi

Bacterial quorum sensing has received much attention in recent years because of its relevance to pathological events such as biofilm formation. Based on the structures of two lead inhibitors (IC₅₀: 35–55 μM ) against autoinducer‐2‐mediated quorum sensing identified through virtual screening, we synthesized 39 analogues and examined their inhibitory activities. Twelve of these new analogues showed equal or better inhibitory activities than the lead inhibitors. The best compound showed an IC₅₀ value of ～6 μM in a whole‐cell assay using Vibrio harveyi as the model organism. The structure–activity relationship is discussed herein.     

Synthesis and Evaluation of Novel Acyclic Nucleoside Phosphonates as Inhibitors of Plasmodium falciparum and Human 6‐Oxopurine Phosphoribosyltransferases

Acyclic nucleoside phosphonates (ANPs) are a promising class of antimalarial therapeutic drug leads that exhibit a wide variety of K_i values for Plasmodium falciparum (Pf) and human hypoxanthine‐guanine‐(xanthine) phosphoribosyltransferases [HG(X)PRTs]. A novel series of ANPs, analogues of previously reported 2‐(phosphonoethoxy)ethyl (PEE) and (R,S)‐3‐hydroxy‐2‐(phosphonomethoxy)propyl (HPMP) derivatives, were designed and synthesized to evaluate their ability to act as inhibitors of these enzymes and to extend our ongoing antimalarial structure–activity relationship studies. In this series, (S)‐3‐hydroxy‐2‐(phosphonoethoxy)propyl (HPEP), (S)‐2‐(phosphonomethoxy)propanoic acid (CPME), or (S)‐2‐(phosphonoethoxy)propanoic acid (CPEE) are the acyclic moieties. Of this group, (S)‐3‐hydroxy‐2‐(phosphonoethoxy)propylguanine (HPEPG) exhibits the highest potency for PfHGXPRT, with a K_i value of 0.1 μM and a K_i value for human HGPRT of 0.6 μM . The crystal structures of HPEPG and HPEPHx (where Hx=hypoxanthine) in complex with human HGPRT were obtained, showing specific interactions with active site residues. Prodrugs for the HPEP and CPEE analogues were synthesized and tested for in vitro antimalarial activity. The lowest IC₅₀ value (22 μM ) in a chloroquine‐resistant strain was observed for the bis‐amidate prodrug of HPEPG.     

Synthesis and Structure–Activity Relationship Studies of 2‐(1,3,4‐Oxadiazole‐2(3H)‐thione)‐3‐amino‐5‐arylthieno[2,3‐b]pyridines as Inhibitors of DRAK2

In recent years, DAPK‐related apoptosis‐inducing protein kinase 2 (DRAK2) has emerged as a promising target for the treatment of a variety of autoimmune diseases and for the prevention of graft rejection after organ transplantation. However, medicinal chemistry optimization campaigns for the discovery of novel small‐molecule inhibitors of DRAK2 have not yet been published. Screening of a proprietary compound library led to the discovery of a benzothiophene analogue that displays an affinity constant (K_d) value of 0.25 μM . Variation of the core scaffold and of the substitution pattern afforded a series of 5‐arylthieno[2,3‐b]pyridines with strong binding affinity (K_d=0.008 μM for the most potent representative). These compounds also show promising activity in a functional biochemical DRAK2 enzyme assay, with an IC₅₀ value of 0.029 μM for the most potent congener. Selectivity profiling of the most potent compounds revealed that they lack selectivity within the DAPK family of kinases. However, one of the less potent analogues is a selective ligand for DRAK2 and can be used as starting point for the synthesis of selective and potent DRAK2 inhibitors.     

A Novel Competitive Class of α‐Glucosidase Inhibitors: (E)‐1‐Phenyl‐3‐(4‐Styrylphenyl)Urea Derivatives

Competitive glycosidase inhibitors are generally sugar mimics that are costly and tedious to obtain because they require challenging and elongated chemical synthesis, which must be stereo‐ and regiocontrolled. Here, we show that readily accessible achiral (E)‐1‐phenyl‐3‐(4‐strylphenyl)ureas are potent competitive α‐glucosidase inhibitors. A systematic synthesis study shows that the 1‐phenyl moiety on the urea is critical for ensuring competitive inhibition, and substituents on both terminal phenyl groups contribute to inhibition potency. The most potent inhibitor, compound 12 (IC₅₀=8.4 μM , K_i=3.2 μM ), manifested a simple slow‐binding inhibition profile for α‐glucosidase with the kinetic parameters k₃=0.005256 μM ^?1 min^?1, k₄=0.003024 min^?1, and ${K{{{\rm app}\hfill \atop {\rm i}\hfill}}}$ =0.5753 μM .     

Development of Novel Selective Peptidomimetics Containing a Boronic Acid Moiety,Targeting the 20S Proteasome as Anticancer Agents

This paper describes the design, synthesis, and biological evaluation of peptidomimetic boronates as inhibitors of the 20S proteasome, a validated target in the treatment of multiple myeloma. The synthesized compounds showed a good inhibitory profile against the ChT‐L activity of 20S proteasome. Compounds bearing a β‐alanine residue at the P2 position were the most active, that is, 3‐ethylphenylamino and 4‐methoxyphenylamino (R)‐1‐{3‐[4‐(substituted)‐2‐oxopyridin‐1(2H)‐yl]propanamido}‐3‐methylbutylboronic acids ( 3 c and 3 d , respectively), and these derivatives showed inhibition constants (K_i) of 17 and 20 nM , respectively. In addition, they co‐inhibited post glutamyl peptide hydrolase activity ( 3 c , K_i=2.57 μM ; 3 d , K_i=3.81 μM ). No inhibition was recorded against the bovine pancreatic α‐chymotrypsin, which thus confirms the selectivity towards the target enzyme. Docking studies of 3 c and related inhibitors into the yeast proteasome revealed the structural basis for specificity. The evaluation of growth inhibitory effects against 60 human tumor cell lines was performed at the US National Cancer Institute. Among the selected compounds, 3 c showed 50 % growth inhibition (GI₅₀) values at the sub‐micromolar level on all cell lines.     

Spiro-Oxindole Skeleton Compounds Are Efficient Inhibitors for Indoleamine 2,3-Dioxygenase 1: An Attractive Target for Tumor Immunotherapy

Indoleamine 2,3-dioxygenase 1 (IDO1) is an attractive heme enzyme for its significant function in cancer immunotherapy. Potent IDO1 inhibitors have been discovered for decades, whereas no clinical drugs are used for cancer treatment up to now. With the goal of developing medically valuable IDO inhibitors, we performed a systematic study of SAR405838 analogs with a spiro-oxindole skeleton in this study. Based on the expression and purification of human IDO1, the inhibitory activity of spiro-oxindole skeleton compounds to IDO1 was evaluated by IC₅₀ and K_i values. The results demonstrated that inhibitor 3 exhibited the highest IDO1 inhibitory activity with IC₅₀ at 7.9 μM among all inhibitors, which is ~six-fold of the positive control (4−PI). Moreover, inhibitor 3 was found to have the most effective inhibition of IDO1 in MCF-7 cancer cells without toxic effects. Molecular docking analysis revealed that the hydrophobic interaction stabilized the binding of inhibitor 3 to the IDO1 active site and made an explanation for the uncompetitive mode of inhibitors. Therefore, this study provides valuable insights into the screen of more potent IDO1 inhibitors for cancer immunotherapy.     

Synthesis and Evaluation of 1‐(1‐(Benzo[b]thiophen‐2‐yl)cyclohexyl)piperidine (BTCP) Analogues as Inhibitors of Trypanothione Reductase

Thirty two analogues of phencyclidine were synthesised and tested as inhibitors of trypanothione reductase (TryR), a potential drug target in trypanosome and leishmania parasites. The lead compound BTCP ( 1 , 1‐(1‐benzo[b]thiophen‐2‐yl‐cyclohexyl) piperidine) was found to be a competitive inhibitor of the enzyme (K_i=1 μM ) and biologically active against bloodstream T. brucei (EC₅₀=10 μM ), but with poor selectivity against mammalian MRC5 cells (EC₅₀=29 μM ). Analogues with improved enzymatic and biological activity were obtained. The structure–activity relationships of this novel series are discussed.     

Discovery,Synthesis and Characterization of a Highly Muscarinic Acetylcholine Receptor (mAChR)‐Selective M5‐Orthosteric Antagonist,VU0488130 (ML381): A Novel Molecular Probe

Of the five G‐protein‐coupled muscarinic acetylcholine receptors (mAChRs; M₁–M₅), M₅ is the least explored and understood due to a lack of mAChR subtype‐selective ligands. We recently performed a high‐throughput functional screen and identified a number of weak antagonist hits that are selective for the M₅ receptor. Here, we report an iterative parallel synthesis and detailed molecular pharmacologic profiling effort that led to the discovery of the first highly selective, central nervous system (CNS)‐penetrant M₅‐orthosteric antagonist, with sub‐micromolar potency (hM₅ IC₅₀=450 nM , hM₅ K_i=340 nM , M₁–M₄ IC₅₀ >30 μM ), enantiospecific inhibition, and an acceptable drug metabolism and pharmacokinetics (DMPK) profile for in vitro and electrophysiology studies. This compound will be a powerful tool and molecular probe for the further investigation into the role of M₅ in addiction and other diseases.