Eyup Akgün

Bivalent Ligands That Target μ Opioid (MOP) and Cannabinoid1 (CB1) Receptors Are Potent Analgesics Devoid of Tolerance

Given that μ opioid (MOP) and canabinoid (CB1) receptors are colocalized in various regions of the central nervous system and have been reported to associate as heteromer (MOP-CB1) in cultured cells, the possibility of functional, endogenous MOP-CB1 in nociception and other pharmacologic effects has been raised. As a first step in investigating this possibility, we have synthesized a series of bivalent ligands 1-5 that contain both μ agonist and CB1 antagonist pharmacophores for use as tools to study the functional interaction between MOP and CB1 receptors in vivo. Immunofluorescent studies on HEK293 cells coexpressing both receptors suggested 5 (20-atom spacer) to be the only member of the series that bridges the protomers of the heteromer. Antinociceptive testing in mice revealed 5 to be the most potent member of the series. As neither a mixture of monovalent ligands 9 + 10 nor bivalents 2-5 produced tolerance in mice, MOR-CB1 apparently is not an important target for reducing tolerance.

Asymmetric synthesis of β-lactams and n-benzoyl-3-phenylisoserines via the staudinger reaction

Abstract Reaction of benzaldimine 5 derived from 2,3,4,6-tetra-O-acetyl-β-D-galactoseamine with acid chloride 6 yields cis β-lactam 7 as a single diastereoisomer. Hydrolysis of β-lactam 7 followed by N-benzoylation provides access toward N-benzoyl (2S,3R)-3-phenylisoserine 9. N-Benzoyl-3-phenylisoserines are important building blocks for the semi-synthesis of the anti-cancer agent taxol.

Ligands that interact with putative MOR-mGluR5 heteromer in mice with inflammatory pain produce potent antinociception

The low effectiveness of morphine and related mu opioid analgesics for the treatment of chronic inflammatory pain is a result of opioid-induced release of proinflammatory cytokines and glutamate that lower the pain threshold. In this regard, the use of opioids with metabotropic glutamate-5 receptor (mGluR5) antagonist has been reported to increase the efficacy of morphine and prevent the establishment of adverse effects during chronic use. Given the presence of opioid receptors (MORs) and mGluR5 in glia and neurons, together with reports that suggest coexpressed MOR/mGluR5 receptors in cultured cells associate as a heteromer, the possibility that such a heteromer could be a target in vivo was addressed by the design and synthesis of a series of bivalent ligands that contain mu opioid agonist and mGluR5 antagonist pharmacophores linked through spacers of varying length (10–24 atoms). The series was evaluated for antinociception using the tail-flick and von Frey assays in mice pretreated with lipopolysaccharide (LPS) or in mice with bone cancer. In LPS-pretreated mice, MMG22 (4c, 22-atom spacer) was the most potent member of the series (intrathecal ED50 ∼9 fmol per mouse), whereas in untreated mice its ED50 was more than three orders of magnitude higher. As members of the series with shorter or longer spacers have ≥500-fold higher ED50s in LPS-treated mice, the exceptional potency of MMG22 may be a result of the optimal bridging of protomers in a putative MOR-mGluR5 heteromer. The finding that MMG22 possesses a >106 therapeutic ratio suggests that it may be an excellent candidate for treatment of chronic, intractable pain via spinal administration.

Induced association of mu opioid (MOP) and type 2 cholecystokinin (CCK2) receptors by novel bivalent ligands

Both mu-opioid (MOP) and type 2 cholecystokinin (CCK2) receptors are present in areas of the central nervous system that are involved in modulation of pain processing. We conducted bioluminescence resonance energy transfer (BRET) studies on COS cells coexpressing MOP and CCK2 receptors to determine whether receptor heterodimerization is involved in such modulation. These studies revealed the absence of constitutive or monovalent ligand-induced heterodimerization. Heterodimerization of MOP and CCK2 receptors therefore is unlikely to be responsible for the opposing effects between morphine and CCK in the CNS. However, association was induced, as indicated by a positive BRET signal, on exposure of the cells to bivalent ligands containing mu-opioid agonist and CCK2 receptor antagonist pharmacophores linked through spacers containing 16-22 atoms but not with a shorter (9-atom) spacer. These studies demonstrate for the first time that an appropriately designed bivalent ligand is capable of inducing association of G-protein-coupled receptors. The finding that opioid tolerance studies with these ligands in mice showed no correlation with the BRET data is consistent with the absence of association of MOP and CCK2 receptors in vivo.

Galactose-Imines in the staudinger reaction

Abstract Staudinger reaction of imines 1 and 2 derived from galactose with a variety of acid chlorides resulted in the formation of two β-lactams with cis configuration, typically in a 60:40 ratio and in good yields. The β-lactams were separated and the absolute stereochemistry of the diastereoisomers was determined by single crystal X-ray analysis and correlation of their 1 H-NMR data.

Targeting putative mu opioid/metabotropic glutamate receptor-5 heteromers produces potent antinociception in a chronic murine bone cancer model.

The therapeutic management of chronic pain associated with many cancers is problematic due to the development of tolerance and other adverse effects during the disease progression. Recently we reported on a bivalent ligand (MMG22) containing both mu agonist and mGluR5 antagonist pharmacophores that produced potent antinociception in mice with LPS-induced acute inflammatory pain via a putative MOR-mGluR5 heteromer. In the present study we have investigated the antinociception of MMG22 in a mouse model of bone cancer pain to determine its effectiveness in reducing this type of chronic nociception. There was a 572-fold increase in the potency of MMG22 over a period of 3-21 days that correlated with the progressive increase in hyperalgesia induced by bone tumor growth following implantation of fibrosarcoma cells in mice. The enhancement of antinociception with the progression of the cancer is possibly due to inhibition of NMDA receptor-mediated hyperalgesia via antagonism of mGluR5 and concomitant activation of MOR by the MMG22-occupied heteromer. Notably, MMG22 was 3.6-million-fold more potent than morphine at PID 21. Since MMG22 exhibited a 250,000-times greater potency than that of a mixture of the mu opioid (M19) agonist and mGluR5 antagonist (MG20) monovalent ligands, the data suggest that targeting the putative MOR-mGluR5 heteromer is far superior to univalent interaction with receptors in reducing tumor-induced nociception. In view of the high potency, long duration (>24h) of action and minimal side effects, MMG22 has the potential to be a superior pharmacological agent than morphine and other opiates in the treatment of chronic cancer pain and to serve as a novel pharmacologic tool.

Synthesis and in vitro characterization of radioiodinatable benzodiazepines selective for type 1 and type 2 cholecystokinin receptors.

Radiolabeled antagonists of specific peptide receptors identify a higher number of receptor binding sites than agonists and may thus be preferable for in vivo tumor targeting. In this study, two novel radioiodinated 1,4-benzodiazepines, (S)-1-(3-iodophenyl)-3-(1-methyl-2-oxo-5-phenyl-2,3-dihydro-1H-benzo[e][1,4]diazepin-3-yl)urea (9) and (R)-1-(3-iodophenyl)-3-(1-methyl-2-oxo-5-phenyl-2,3-dihydro-1H-benzo[e][1,4]diazepin-3-yl)urea (7), were developed. They were characterized in vitro as high affinity selective antagonists at cholecystokinin types 1 and 2 (CCK(1) and CCK(2)) receptors using receptor binding, calcium mobilization, and internalization studies. Their binding to human tumor tissues was assessed with in vitro receptor autoradiography and compared with an established peptidic CCK agonist radioligand. The (125)I-labeled CCK(1) receptor-selective compound 9 often revealed a substantially higher amount of CCK(1) receptor binding sites in tumors than the agonist (125)I-CCK. Conversely, the radioiodinated CCK(2) receptor-selective compound 7 showed generally weaker tumor binding than (125)I-CCK. In conclusion, compound 9 is an excellent radioiodinated nonpeptidic antagonist ligand for direct and selective labeling of CCK(1) receptors in vitro. Moreover, it represents a suitable candidate to test antagonist binding to CCK(1) receptor-expressing tumors in vivo.

Binding potency of 6-nitroquipazine analogues for the 5-hydroxytryptamine reuptake complex

Abstract— The in‐vitro inhibition constants (Ki) of nine structural analogues of the potent 5‐hydroxytryptamine (5‐HT)‐uptake inhibitor, 6‐nitroquipazine, were determined to assess the structure‐affinity relationship of these derivatives. The goal of these studies was to determine those positions on 6‐nitroquipazine that could be derivatized without significantly decreasing the affinity of the drug for the binding site, so that radiolabels such as 123I, 76Br or 18F might be appended for in‐vivo imaging studies of the 5‐HT reuptake system. Using bromine as a steric probe, the rank order of potency of bromine‐substituted 6‐nitroquipazine analogues for inhibiting the binding of [3H]paroxetine to the 5‐HT reuptake binding site was: 8‐<3‐<7‐<4‐<5‐bromo. The in‐vitro equipotent molar ratio (EPMR, Ki (analogue)/Ki(6‐nitroquipazine)) of the 5‐bromo analogue was 0·57, indicating that this analogue had greater affinity for the 5‐HT reuptake complex than 6‐nitroquipazine. Derivatization at the 5‐position with fluorine and iodine also resulted in potent compounds with EPMR values of 1·1 and 0·83, respectively. Substitution of quipazine with bromo, cyano, and formyl groups at the 6‐position produced less potent compounds than the 6‐nitro group. Based upon the high affinities of the 5‐bromo‐, 5‐fluoro‐ and 5‐iodo‐6‐nitroquipazines for the 5‐HT reuptake complex, these compounds are candidates for radiolabelling for in‐vivo studies of the 5‐HT reuptake site.

Inhibition of Inflammatory and Neuropathic Pain by Targeting a Mu Opioid Receptor/Chemokine Receptor5 Heteromer (MOR-CCR5).

Chemokine release promotes cross-talk between opioid and chemokine receptors that in part leads to reduced efficacy of morphine in the treatment of chronic pain. On the basis of the possibility that a MOR-CCR5 heteromer is involved in such cross-talk, we have synthesized bivalent ligands (MCC series) that contain mu opioid agonist and CCR5 antagonist pharmacophores linked through homologous spacers (14-24 atoms). When tested on lipopolysaccharide-inflamed mice, a member of the series (MCC22; 3e) with a 22-atom spacer exhibited profound antinociception (i.t. ED50 = 0.0146 pmol/mouse) that was 2000× greater than morphine. Moreover, MCC22 was ~3500× more potent than a mixture of mu agonist and CCR5 antagonist monovalent ligands. These data strongly suggest that MCC22 acts by bridging the protomers of a MOR-CCR5 heteromer having a TM5,6 interface. Molecular simulation studies are consistent with such bridging. This study supports the MOR-CCR5 heteromer as a novel target for the treatment of chronic pain.

Molecular basis for binding and subtype selectivity of 1,4-benzodiazepine antagonist ligands of the cholecystokinin receptor.

Background: Allosteric ligands targeting cholecystokinin receptors are needed. Results: Stereochemically distinct iodinated 1,4-benzodiazepine antagonists of type 1 and 2 cholecystokinin receptors dock to analogous intramembranous pockets that have distinct shape and molecular determinants. Conclusion: The geometry of the binding pockets and specific residue interactions are unique for each receptor. Significance: The predictive power of these insights should be useful in the discovery of lead compounds and in their refinement. Allosteric binding pockets in peptide-binding G protein-coupled receptors create opportunities for the development of small molecule drugs with substantial benefits over orthosteric ligands. To gain insights into molecular determinants for this pocket within type 1 and 2 cholecystokinin receptors (CCK1R and CCK2R), we prepared a series of receptor constructs in which six distinct residues in TM2, -3, -6, and -7 were reversed. Two novel iodinated CCK1R- and CCK2R-selective 1,4-benzodiazepine antagonists, differing only in stereochemistry at C3, were used. When all six residues within CCK1R were mutated to corresponding CCK2R residues, benzodiazepine selectivity was reversed, yet peptide binding selectivity was unaffected. Detailed analysis, including observations of gain of function, demonstrated that residues 6.51, 6.52, and 7.39 were most important for binding the CCK1R-selective ligand, whereas residues 2.61 and 7.39 were most important for binding CCK2R-selective ligand, although the effect of substitution of residue 2.61 was likely indirect. Ligand-guided homology modeling was applied to wild type receptors and those reversing benzodiazepine binding selectivity. The models had high predictive power in enriching known receptor-selective ligands from related decoys, indicating a high degree of precision in pocket definition. The benzodiazepines docked in similar poses in both receptors, with C3 urea substituents pointing upward, whereas different stereochemistry at C3 directed the C5 phenyl rings and N1 methyl groups into opposite orientations. The geometry of the binding pockets and specific interactions predicted for ligand docking in these models provide a molecular framework for understanding ligand selectivity at these receptor subtypes. Furthermore, the strong predictive power of these models suggests their usefulness in the discovery of lead compounds and in drug development programs.