The μ opioid receptor (MOR) is a prominent member of the G protein-coupled receptor family and the molecular target of morphine and other opioid drugs. Despite the long tradition of MOR-targeting drugs, still little is known about the ligand-receptor interactions and structure-function relationships underlying the distinct biological effects upon receptor activation or inhibition. With the resolved crystal structure of the β-funaltrexamine-MOR complex, we aimed at the discovery of novel agonists and antagonists using virtual screening tools, i.e. docking, pharmacophore- and shape-based modeling. We suggest important molecular interactions, which active molecules share and distinguish agonists and antagonists. These results allowed for the generation of theoretically validated in silico workflows that were employed for prospective virtual screening. Out of 18 virtual hits evaluated in in vitro pharmacological assays, three displayed antagonist activity and the most active compound significantly inhibited morphine-induced antinociception. The new identified chemotypes hold promise for further development into neurochemical tools for studying the MOR or as potential therapeutic lead candidates.
A systems view of G protein-coupled receptor (GPCR) signaling in its native environment is central to the development of GPCR therapeutics with fewer side effects. Using the kappa opioid receptor (KOR) as a model, we employed high-throughput phosphoproteomics to investigate signaling induced by structurally diverse agonists in five mouse brain regions. Quantification of 50,000 different phosphosites provided a systems view of KOR in vivo signaling, revealing novel mechanisms of drug action. Thus, we discovered enrichment of the mechanistic target of rapamycin (mTOR) pathway by U-50,488H, an agonist causing aversion, which is a typical KOR-mediated side effect. Consequently, mTOR inhibition during KOR activation abolished aversion while preserving beneficial antinociceptive and anticonvulsant effects. Our results establish high-throughput phosphoproteomics as a general strategy to investigate GPCR in vivo signaling, enabling prediction and modulation of behavioral outcomes.
Although the µ opioid receptor (MOR) was pharmacologically and biochemically identified in binding studies forty years ago, its structure, function, and true complexity only have emerged after its cloning in 1993. Continuous efforts from many laboratories have greatly advanced our understanding of MORs, ranging from their anatomic distribution to cellular and molecular mechanisms, and from cell lines to in vivo systems. The MOR is recognized as the main target for effective pain relief, but its involvement in many other physiological functions has also been recognized. This review provides a synopsis on the history of research on MORs and ligands acting at the MOR with the focus on their clinical and potential use as therapeutic drugs, or as valuable research tools. Since the elucidation of the chemical structure of morphine and the characterization of endogenous opioid peptides, research has stimulated the development of new generations of MOR ligands with distinct pharmacological profiles (agonist, antagonist, mixed agonist/antagonist and partial agonist) or site of action (central/peripheral). Discovery of therapeutically useful morphine-like drugs and innovative drugs with new scaffolds, with several outstanding representatives, is discussed. Extensive efforts on modifications of endogenous peptides to attain stable and MOR selective analogs are overviewed with stimulating results for the development of peptide-based pharmaceuticals. With pharmacophore modeling as an important tool in drug discovery, application of modern computational methodologies for the development of morphinans as new MOR ligands is described. Moreover, the crystal structure of the MOR available today will enable the application of structure-based approaches to design better drugs for the management of pain, addiction and other human diseases, where MORs play a key role.
Background and purposeThe κ receptor has a central role in modulating neurotransmission in central and peripheral neuronal circuits that subserve pain and other behavioural responses. Although κ receptor agonists do not produce euphoria or lead to respiratory suppression, they induce dysphoria and sedation. We hypothesized that brain‐penetrant κ receptor ligands possessing biased agonism towards G protein signalling over β‐arrestin2 recruitment would produce robust antinociception with fewer associated liabilities.Experimental approachTwo new diphenethylamines with high κ receptor selectivity, HS665 and HS666, were assessed following i.c.v. administration in mouse assays of antinociception with the 55°C warm‐water tail withdrawal test, locomotor activity in the rotorod and conditioned place preference. The [35S]‐GTPγS binding and β‐arrestin2 recruitment in vitro assays were used to characterize biased agonism.Key resultsHS665 (κ receptor agonist) and HS666 (κ receptor partial agonist) demonstrated dose‐dependent antinociception after i.c.v. administration mediated by the κ receptor. These highly selective κ receptor ligands displayed varying biased signalling towards G protein coupling in vitro, consistent with a reduced liability profile, reflected by reduced sedation and absence of conditioned place aversion for HS666.Conclusions and implicationsHS665 and HS666 activate central κ receptors to produce potent antinociception, with HS666 displaying pharmacological characteristics of a κ receptor analgesic with reduced liability for aversive effects correlating with its low efficacy in the β‐arrestin2 signalling pathway. Our data provide further understanding of the contribution of central κ receptors in pain suppression, and the prospect of dissociating the antinociceptive effects of HS665 and HS666 from κ receptor‐mediated adverse effects.
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