Asymmetric syntheses of (+)- and (–)-collybolide enable reevaluation of kappa-opioid receptor agonism

The fungal metabolite collybolide attracted attention as a non-nitrogenous, potent and biased agonist of the kappa-opioid receptor (KOR). Here we report a 10-step asymmetric synthesis of this complex sesquiterpene that enables facile access to either enantiomer. The synthesis relies on a diastereoselective α-benzoyloxylation to install the buried C6 benzoate and avoid irreversible translactonization of the congested, functionally dense core. Neither enantiomer, however, exhibited KOR agonism, indicating that collybolide has been mischaracterized as a KOR agonist and leaving open the basis for antipruritic effects in mice.

Asymmetric syntheses of (+)- and (–)-collybolide enable reevaluation of kappa-opioid receptor agonism

The fungal metabolite collybolide attracted attention as a non-nitrogenous, potent and biased agonist of the kappa-opioid receptor (KOR). Here we report a 10-step asymmetric synthesis of this complex sesquiterpene that enables facile access to either enantiomer. The synthesis relies on a diastereoselective α-benzoyloxylation to install the buried C6 benzoate and avoid irreversible translactonization of the congested, functionally dense core. Neither enantiomer, however, exhibited KOR agonism, raising the specter of a yet-unidentified contaminant responsible for the reported activity.

The Salvinorin Analogue, Ethoxymethyl Ether Salvinorin B, Promotes Remyelination in Preclinical Models of Multiple Sclerosis

Multiple sclerosis is a neurodegenerative disease associated with demyelination and neuroinflammation in the central nervous system. There is an urgent need to develop remyelinating therapies to better treat multiple sclerosis and other demyelinating diseases. The kappa opioid receptor (KOR) has been identified as a potential target for the development of remyelinating therapies; however, prototypical KOR agonists, such as U50,488 have side effects, which limit clinical use. In the current study, we investigated a Salvinorin A analog, ethoxymethyl ether Salvinorin B (EOM SalB) in two preclinical models of demyelination in C57BL/6J mice. We showed that in cellular assays EOM SalB was G-protein biased, an effect often correlated with fewer KOR-mediated side effects. In the experimental autoimmune encephalomyelitis model, we found that EOM SalB (0.1–0.3 mg/kg) effectively decreased disease severity in a KOR-dependent manner and led to a greater number of animals in recovery compared to U50,488 treatment. Furthermore, EOM SalB treatment decreased immune cell infiltration and increased myelin levels in the central nervous system. In the cuprizone-induced demyelination model, we showed that EOM SalB (0.3 mg/kg) administration led to an increase in the number of mature oligodendrocytes, the number of myelinated axons and the myelin thickness in the corpus callosum. Overall, EOM SalB was effective in two preclinical models of multiple sclerosis and demyelination, adding further evidence to show KOR agonists are a promising target for remyelinating therapies.

Self-Administration of Entactogen Psychostimulants Dysregulates Gamma-Aminobutyric Acid (GABA) and Kappa Opioid Receptor Signaling in the Central Nucleus of the Amygdala of Female Wistar Rats

Male rats escalate intravenous self-administration of entactogen psychostimulants, 3,4-methylenedioxymethcathinone (methylone) and 3,4-methylenedioxymethamphetamine (MDMA) under extended access conditions, as with typical psychostimulants. Here, we investigated whether female rats escalate self-administration of methylone, 3,4-methylenedioxypentedrone (pentylone), and MDMA and then studied consequences of MDMA and pentylone self-administration on GABAA receptor and kappa opioid receptor (KOR) signaling in the central nucleus of the amygdala (CeA), a brain area critically dysregulated by extended access self-administration of alcohol or cocaine. Adult female Wistar rats were trained to self-administer methylone, pentylone, MDMA (0.5 mg/kg/infusion), or saline-vehicle using a fixed-ratio 1 response contingency in 6-h sessions (long-access: LgA) followed by progressive ratio (PR) dose-response testing. The effects of pentylone-LgA, MDMA-LgA and saline on basal GABAergic transmission (miniature post-synaptic inhibitory currents, mIPSCs) and the modulatory role of KOR at CeA GABAergic synapses were determined in acute brain slices using whole-cell patch-clamp. Methylone-LgA and pentylone-LgA rats similarly escalated their drug intake (both obtained more infusions compared to MDMA-LgA rats), however, pentylone-LgA rats reached higher breakpoints in PR tests. At the cellular level, baseline CeA GABA transmission was markedly elevated in pentylone-LgA and MDMA-LgA rats compared to saline-vehicle. Specifically, pentylone-LgA was associated with increased CeA mIPSC frequency (GABA release) and amplitude (post-synaptic GABAA receptor function), while mIPSC amplitudes (but not frequency) was larger in MDMA-LgA rats compared to saline rats. In addition, pentylone-LgA and MDMA-LgA profoundly disrupted CeA KOR signaling such as both KOR agonism (1 mM U50488) and KOR antagonism (200 nM nor-binaltorphimine) decreased mIPSC frequency suggesting recruitment of non-canonical KOR signaling pathways. This study confirms escalated self-administration of entactogen psychostimulants under LgA conditions in female rats which is accompanied by increased CeA GABAergic inhibition and altered KOR signaling. Collectively, our study suggests that CeA GABA and KOR mechanisms play a critical role in entactogen self-administration like those observed with escalation of alcohol or cocaine self-administration.

Tackling the opioid crisis - development of kappa-opioid receptor peptide agonists for safer analgesic therapy

The kappa opioid receptor (KOPr) has exceptional potential as an analgesic target, seemingly devoid of the many peripheral side-effects of Mu receptors. Kappa-selective, small molecule pharmaceutical agents have been developed, but centrally mediated side effects have the limited their clinical translation. Here, we modify an active endogenous Dynorphin peptide with the aim of improving drug-likeness and developing safer KOPr agonists for clinical use. Using rational, iterative design and modern peptide chemistry, we developed a series of potent, selective and metabolically stable peptides from Dynorphin 1-7. Peptides were assessed for cAMP-modulation against Kappa, Mu and Delta opioid receptors, metabolic stability, KOPr specificity and binding, and interrogated for in vitro desensitisation and pERK signalling capability. Finally, lead peptides were evaluated for efficacy in Freund’s complete adjuvant rat model of inflammatory nociception. A library of 70 peptides was synthesised and assessed for pharmacological and metabolic stability factors. At least 10 peptide candidates showed low nanomolar activity (˂50 nM) in a cAMP assay, specificity for KORr, and plasma half-life >60 min, with 6 candidates also stable in trypsin. None of the selected peptides showed pERK activity, with a bias towards cAMP signalling. In vivo, KA305 and KA311 showed anti-nociception opioid receptor-specific activity comparable to morphine and U50 844. These highly potent and metabolically stable peptides are promising opioid analgesic leads for clinical translation. Since they are biased peptide KOPr agonists, it is plausible they lack many of the most significant side effects, such as tolerance, addiction, sedation and euphoria/dysphoria, common to opioid analgesics.

Functional Characterization of Spinocerebellar Ataxia Associated Dynorphin A Mutant Peptides

Mutations in the prodynorphin gene (PDYN) are associated with the development of spinocerebellar ataxia type 23 (SCA23). Pathogenic missense mutations are localized predominantly in the PDYN region coding for the dynorphin A (DynA) neuropeptide and lead to persistently elevated mutant peptide levels with neurotoxic properties. The main DynA target in the central nervous system is the kappa opioid receptor (KOR), a member of the G-protein coupled receptor family, which can elicit signaling cascades mediated by G-protein dissociation as well as β-arrestin recruitment. To date, a thorough analysis of the functional profile for the pathogenic SCA23 DynA mutants at KOR is still missing. To elucidate the role of DynA mutants, we used a combination of assays to investigate the differential activation of G-protein subunits and β-arrestin. In addition, we applied molecular modelling techniques to provide a rationale for the underlying mechanism. Our results demonstrate that DynA mutations, associated with a severe ataxic phenotype, decrease potency of KOR activation, both for G-protein dissociation as well as β-arrestin recruitment. Molecular modelling suggests that this loss of function is due to disruption of critical interactions between DynA and the receptor. In conclusion, this study advances our understanding of KOR signal transduction upon DynA wild type or mutant peptide binding.

Investigating the anti-cocaine effects of novel kappa opioid receptor agonists: Behavioural and cellular actions of Salvinorin A analogues

<p>Acute kappa opioid receptor (KOPr) activation by traditional agonists produces antiaddiction properties, but side effects such as sedation and depression prevent their clinical use. The novel KOPr agonist salvinorin A (Sal A), isolated from the plant Salvia divinorum, is a potent and selective KOPr agonist with a unique non-nitrogenous structure. Sal A possesses anti-addiction effects with less side effects than traditional KOPr agonists, but its short duration of action limits its therapeutic usefulness. To test the hypothesis that longer acting structural analogues of Sal A may yield a new class of therapeutics, the anti-cocaine effects of Sal A analogues such as 16-bromosalvinorin A (16-brSal A), ethoxymethyl ether salvinorin B (EOM Sal B), and methoxymethyl ether salvinorin B (MOM Sal B) were evaluated. 16-brSal A (1.0 mg/kg) displayed a longer duration of action in mice compared to Sal A, evidenced using the tail flick test (p<0.05). Both 16-brSal A and EOM Sal B produced dose-dependent decreases in cocaine-induced reinstatement of drug seeking (p<0.05). On the other hand, 16-brSal A (1.0 mg/kg) but not MOM Sal B (0.3 mg/kg) attenuated cocaine-induced hyperactivity (p<0.05), although both compounds showed no sedative effects in the locomotor activity test in rats. This indicates the superior behavioural anti-cocaine profile of 16-brSal A at its minimum effective dose. These three compounds, together with another analogue that also decreased cocaineinduced drug seeking, β-tetrahydropyran salvinorin B (β-THP Sal B), were screened for typical KOPr-mediated side effects using the minimal effective doses that attenuated drug seeking. MOM Sal B but not EOM Sal B (0.1 mg/kg), β-THP Sal B (1.0 mg/kg), or 16-brSal A produced depressive-like effects in the forced swim test (FST) in rats (p<0.05). However, EOM Sal B displayed a reduction in swimming time coupled with an increase in climbing duration in the FST (p<0.05). On the other hand, β-THP Sal B (p<0.001, between 30 – 45 min) and EOM Sal B (p<0.05, between 15 – 30 min) significantly increased sucrose intake in the rat sucrose self-administration model at different time intervals. 16-brSal A, however, produced no significant changes in natural reward intake measured by sucrose self-administration. The improved behavioural profile of 16-brSal A extended to a lack of anxiogenic effects. No significant anxiety-like behaviour was seen in the light dark or elevated plus maze, although aversion was observed in the conditioned place aversion paradigm (p<0.05). The low incidence of adverse effects of 16-brSal A compared to other iv Sal A analogues in behavioural models prompted additional cellular studies of this KOPr agonist. As the anti-cocaine effects of KOPr agonists have been attributed to their ability to modulate dopamine (DA) levels, 16-brSal A was examined for its ability to regulate dopamine transporter (DAT) function. DAT function was determined in vitro by determining uptake of a fluorescent substrate, ASP+, in HEK-293 cells expressing YFP-DAT and myc-KOPr. Ex vivo studies were also conducted by measuring DA uptake in isolated, minced rat dorsal striatum and nucleus accumbens using rotating disk electrode voltammetry. 16-brSal A significantly increased DAT function in both the in vitro (10 μM) and ex vivo (500 nM) models (p<0.05), an effect that was dependent on extracellular regulated kinase 1/2 (ERK1/2). Since late phase ERK1/2 and p38 kinase activation have been attributed to negative KOPr behavioural responses, the effects of 16-brSal A on these pathways were also examined. Western blotting studies revealed that 16-brSal A selectively activated only the early (5 – 15 min) but not late phase (120 – 180 min) ERK1/2 pathway in HEK-293 cells as well as rat dorsal striatum, prefrontal cortex, and nucleus accumbens (p<0.05). 16-brSal A also produced no significant activation of p38 kinase in the dorsal striatum or prefrontal cortex of rats, although significant phosphorylation was seen in the nucleus accumbens (p<0.05). The ability of 16-brSal A to produce desired behavioural anti-addiction effects with fewer adverse effects, matched with its regulation of KOPr signalling pathways, suggests that it may possibly be a functionally selective agonist that preferentially activates the G-protein signalling pathway at the KOPr. Since understanding the potential use of novel KOPr agonists in different phases of the addiction cycle is crucial to ensure effective administration of therapies, Sal A and 16-brSal A were tested in rats self-administering cocaine on the long access (Sal A) and progressive ratio (Sal A and 16-brSal A) schedules. Although no differences in cocaine responding were seen with KOPr agonist treatment in either paradigms, a higher dose or concurrent infusions of KOPr agonist with cocaine may improve the responses observed. Overall, the novel KOPr agonist, 16-brSal A has excellent potential as a pharmacotherapy due to its anti-cocaine effects and minimal adverse side effect profile. This is the first study to examine in detail the behavioural and cellular actions of 16-brSal A, and supports previous reports of Sal A-derived KOPr agonists as prospective therapeutics for cocaine abuse.</p>

Investigating the anti-cocaine effects of novel kappa opioid receptor agonists: Behavioural and cellular actions of Salvinorin A analogues

<p>Acute kappa opioid receptor (KOPr) activation by traditional agonists produces antiaddiction properties, but side effects such as sedation and depression prevent their clinical use. The novel KOPr agonist salvinorin A (Sal A), isolated from the plant Salvia divinorum, is a potent and selective KOPr agonist with a unique non-nitrogenous structure. Sal A possesses anti-addiction effects with less side effects than traditional KOPr agonists, but its short duration of action limits its therapeutic usefulness. To test the hypothesis that longer acting structural analogues of Sal A may yield a new class of therapeutics, the anti-cocaine effects of Sal A analogues such as 16-bromosalvinorin A (16-brSal A), ethoxymethyl ether salvinorin B (EOM Sal B), and methoxymethyl ether salvinorin B (MOM Sal B) were evaluated. 16-brSal A (1.0 mg/kg) displayed a longer duration of action in mice compared to Sal A, evidenced using the tail flick test (p<0.05). Both 16-brSal A and EOM Sal B produced dose-dependent decreases in cocaine-induced reinstatement of drug seeking (p<0.05). On the other hand, 16-brSal A (1.0 mg/kg) but not MOM Sal B (0.3 mg/kg) attenuated cocaine-induced hyperactivity (p<0.05), although both compounds showed no sedative effects in the locomotor activity test in rats. This indicates the superior behavioural anti-cocaine profile of 16-brSal A at its minimum effective dose. These three compounds, together with another analogue that also decreased cocaineinduced drug seeking, β-tetrahydropyran salvinorin B (β-THP Sal B), were screened for typical KOPr-mediated side effects using the minimal effective doses that attenuated drug seeking. MOM Sal B but not EOM Sal B (0.1 mg/kg), β-THP Sal B (1.0 mg/kg), or 16-brSal A produced depressive-like effects in the forced swim test (FST) in rats (p<0.05). However, EOM Sal B displayed a reduction in swimming time coupled with an increase in climbing duration in the FST (p<0.05). On the other hand, β-THP Sal B (p<0.001, between 30 – 45 min) and EOM Sal B (p<0.05, between 15 – 30 min) significantly increased sucrose intake in the rat sucrose self-administration model at different time intervals. 16-brSal A, however, produced no significant changes in natural reward intake measured by sucrose self-administration. The improved behavioural profile of 16-brSal A extended to a lack of anxiogenic effects. No significant anxiety-like behaviour was seen in the light dark or elevated plus maze, although aversion was observed in the conditioned place aversion paradigm (p<0.05). The low incidence of adverse effects of 16-brSal A compared to other iv Sal A analogues in behavioural models prompted additional cellular studies of this KOPr agonist. As the anti-cocaine effects of KOPr agonists have been attributed to their ability to modulate dopamine (DA) levels, 16-brSal A was examined for its ability to regulate dopamine transporter (DAT) function. DAT function was determined in vitro by determining uptake of a fluorescent substrate, ASP+, in HEK-293 cells expressing YFP-DAT and myc-KOPr. Ex vivo studies were also conducted by measuring DA uptake in isolated, minced rat dorsal striatum and nucleus accumbens using rotating disk electrode voltammetry. 16-brSal A significantly increased DAT function in both the in vitro (10 μM) and ex vivo (500 nM) models (p<0.05), an effect that was dependent on extracellular regulated kinase 1/2 (ERK1/2). Since late phase ERK1/2 and p38 kinase activation have been attributed to negative KOPr behavioural responses, the effects of 16-brSal A on these pathways were also examined. Western blotting studies revealed that 16-brSal A selectively activated only the early (5 – 15 min) but not late phase (120 – 180 min) ERK1/2 pathway in HEK-293 cells as well as rat dorsal striatum, prefrontal cortex, and nucleus accumbens (p<0.05). 16-brSal A also produced no significant activation of p38 kinase in the dorsal striatum or prefrontal cortex of rats, although significant phosphorylation was seen in the nucleus accumbens (p<0.05). The ability of 16-brSal A to produce desired behavioural anti-addiction effects with fewer adverse effects, matched with its regulation of KOPr signalling pathways, suggests that it may possibly be a functionally selective agonist that preferentially activates the G-protein signalling pathway at the KOPr. Since understanding the potential use of novel KOPr agonists in different phases of the addiction cycle is crucial to ensure effective administration of therapies, Sal A and 16-brSal A were tested in rats self-administering cocaine on the long access (Sal A) and progressive ratio (Sal A and 16-brSal A) schedules. Although no differences in cocaine responding were seen with KOPr agonist treatment in either paradigms, a higher dose or concurrent infusions of KOPr agonist with cocaine may improve the responses observed. Overall, the novel KOPr agonist, 16-brSal A has excellent potential as a pharmacotherapy due to its anti-cocaine effects and minimal adverse side effect profile. This is the first study to examine in detail the behavioural and cellular actions of 16-brSal A, and supports previous reports of Sal A-derived KOPr agonists as prospective therapeutics for cocaine abuse.</p>