PERIPHERALLY RESTRICTED OPIOID CONJUGATES AND ITS USE AS PHARMACOLOGICAL PROBES AND POTENTIAL THERAPEUTICS

Tuhin, Md Tariqul Haque

01 January 2022

Opioid-induced constipation (OIC) is one of the major adverse effects of opioid analgesics used by millions of patients each year. While progress has been made, there remains a significant unmet medical need in the treatment of OIC. Major gaps remain in our understanding of the role of the gastrointestinal tract and central nervous system (CNS) in precipitating OIC. For the last four decades, numerous investigations to study the sites of action of opioid analgesics have utilized peripherally acting mu-opioid receptor antagonists (PAMORAs), which have been incorrectly believed to have limited penetration across the blood-brain barrier (BBB). Several preclinical and clinical reports indicate that significant amounts of PAMORAs penetrate the BBB quite readily. As a result, the usage of current PAMORAs have resulted in misunderstandings of the role of the CNS and gastrointestinal tract in causing side effects such as opioid-induced constipation (OIC). We have developed a transthyretin-based novel drug delivery approach for restricting the passage of small molecules across the BBB. Our approach involves endowing the opioid agonist/antagonist with the selective transthyretin ligand, AG10. The newly synthesized naloxone- and oxycodone-based conjugates have demonstrated superior peripheral selectivity, improved pharmacokinetics, and efficacy in rats compared to other clinically used PAMORAs. Here we present chemical synthesis, in vitro binding and stability studies, as well as pharmacokinetic and pharmacodynamic evaluations of the AG10-opioid conjugates in rats. Our AG10-based PAMORA allowed us to obtain new insights into the important role of mu-opioid receptors in the central nervous system (CNS) in causing constipation. Additionally, our results demonstrate for the first time that synergy between mu-opioid receptors in the central nervous system and the gastrointestinal tract is crucial to the understanding of OIC and the development of effective treatment regimens. These findings contradict prior ideas that OIC was caused by a mechanism that involves primarily the gastrointestinal mu-opioid receptors. Moreover, we confirmed our findings by a AG10-oxycodone conjugate, a peripherally restricted opioid agonist. This molecule demonstrated the predominant role of CNS in OIC precipitation. The newly synthesized AG10-opioid conjugates represent a novel class of pharmacological probes that will aid in our understanding of OIC and other undesirable adverse effects of opioids. In addition, these conjugates have been evaluated for their potential therapeutic value in the preclinical studies. Collectively our approach to limit the BBB penetration of opioids will contribute to develop safer and more effective opioid medications.

Gastrointestinal Transit

mu-opioid receptor

Opioid Antagonists

Opioid-induced constipation

Opioids

PAMORA

Pharmaceutical sciences

Pharmacology

Chemistry

Chemistry

Medicinal-Pharmaceutical Chemistry

Medicine and Health Sciences

Pharmacy and Pharmaceutical Sciences

Long-Term Opiate-Induced Adaptations in Lateral Paracapsular Neurons of the Basolateral Amygdala

Werner, Sara Jane

09 April 2020

Increases in basolateral amygdala (BLA) activity drive avoidance-seeking behavior that may be associated with stress induced drug seeking. Activity of BLA pyramidal neurons is regulated by local and paracapsular gamma aminobutyric acid (GABA) interneurons. The lateral paracapsular interneurons (LPCs) border the external capsule, receive dense cortical/thalamic input and provide feed-forward inhibition onto BLA principle neurons. The GABAergic LPCs also express high concentrations of g-protein coupled µ-opioid receptors (MORs). Therefore, the effects of opiates on LPC activity and local GABA release were examined. Fluorescently double labeled LPCs were observed in glutamate decarboxylase (GAD) 65-mcherry/GAD67-green fluorescent protein (GFP) transgenic mice. Whole-cell electrophysiology experiments demonstrated that acute exposure to [D-Ala2, N-Me-Phe4, Gly5-ol]-enkephalin (DAMGO; a synthetic selective MOR agonist), reduced LPC firing and spontaneous inhibitory postsynaptic current (sIPSC) frequency in LPCs, with no apparent effect on spontaneous excitatory currents (sEPSCs). Current injection induced firing in LPC neurons, but less effectively than in saline controls. Morphine-exposed mice (10mg/kg/day, across 5 days, 1-2 days off) had increased sIPSCs compared to saline-injected controls, as well as enhanced adenylyl cyclase (AC) activity. Together these data show that LPC neurons are a highly sensitive targets for opiate-induced inhibition, and that long-term opiate exposure results in impaired LPC excitability, possibly contributing to anxiety observed during opiate withdrawal.

lateral paracapsular cells

basolateral amygdala

morphine

addiction

anxiety

mu-opioid receptor

chronic exposure

withdrawal

electrophysiology

whole-cell

patch clamp

Family, Life Course, and Society

Neuronal and Molecular Adaptations of GABA Neurons in the Ventral Tegmental Area to Chronic Alcohol

Hales, Kimberly

03 December 2007

The purpose of this thesis project was to examine the effects of chronic alcohol on the excitability and molecular adaptation of GABA neurons of the ventral tegmental area (VTA). GABA neurons are of interest with regards to ethanol intoxication, reinforcement, and dependence due to their widespread distribution and connectivity to mesocorticolimbic dopamine (DA) neurons implicated in alcohol reward and addiction. Since we have previously shown adaptation of VTA GABA neuron firing rate to chronic ethanol (Gallegos, Criado et al. 1999) and suppression of gap-junction (GJ) mediated coupling between these neurons by acute ethanol (Stobbs, Ohran et al. 2004), we wanted to further characterize the effects of chronic ethanol on VTA GABA neuron excitability, electrical coupling and molecular adaptation. In particular, we analyzed the GJ mediated coupling and protein regulation of VTA GABA neurons following a three week period of continuous ethanol exposure via liquid diet. Although some animals showed tolerance, there was no significant tolerance to ethanol inhibition of GJ-mediated electrical coupling. In addition, we were able to characterize differences in mRNA expression levels for the DA synthesizing enzyme tyrosine hydroxylase (TH), the DA D2 receptor and the NMDAR2B receptor subunit in DA versus GABA neurons, all three of which were expressed at higher levels in DA neurons. We also determined the effects of chronic ethanol on mRNA levels of these same proteins as well as μ-opioid receptors (μORs) and connexin-36 (Cx36) GJs. Most significantly, we found a down-regulation of the DA D2 receptor, confirming that molecular modification occurs in these VTA GABA neurons with chronic alcohol. While we reject our hypothesis that acute ethanol inhibition of VTA GABA neuron electrical coupling would undergo tolerance to chronic ethanol in these non-dependent rats, which was the focus of this thesis, it remains to be determined if tolerance to chronic ethanol might be obtained in ethanol-dependent rats.

alcohol

ventral tegmental area

addiction

Dopamine D2

tyrosine hydroxylase

connexin-36

mu-opioid receptor

GABA neuron

GAD

dopamine neuron

liquid diet

Scn4b

Neuroscience and Neurobiology

Development of Pharmacologically Distinct Opioid Analgesics

Patel, Shivani

29 September 2022

Opioid analgesics have been a major contribution to pain therapy with opioids being used as an effective treatment for various recalcitrant pain conditions. The drug class has come under increased scrutiny due to the raising concerns about the public health crisis of opioid misuse and addiction, thereby increasing the need for alternative and safer analgesics. The exploration of alternative pharmacotherapy for pain management has led to an increasing paradigm shift towards the development of a single-drug-multiple-target approach that takes inspiration from numerous naturally occurring drugs. The mu-opioid receptor has been the primary target for the management of pain; however, the voltage-gated sodium channel Nav1.7 is gaining attention as a putative antinociceptive target based on human genetic evidence. The proposed research aims to develop multi-target directed ligands (MTDL) that modulates two key targets for pain perception, the MOR, and Nav1.7 to generate analgesics with reduced side effects and enhanced analgesia. This will be achieved by exploiting polypharmacology to develop hybrid analgesia in two ways: (i) performing structure-activity relationship (SAR) studies to design a single drug with two pharmacophores that specifically interacts with both the targets (ii) exploiting in silico techniques by performing structure-based virtual ligand screening (VLS) of a chemical library. In our work, we report that through SAR studies and molecular docking studies that the designed compounds having in combination the pharmacophore of PZM21 and aryl sulfonamide demonstrate significant interactions between the active compounds and both the MOR and Nav1.7 proteins. This study also reports the first ever bifunctional virtual ligand screening where a library consisting of over a million compounds was screened for bifunctional activity at the MOR and the Nav1.7 ion channel. We also report the development of a novel mechanism-specific membrane potential assay to that can be used to screen for subtype selective Nav1.7 inhibitors. The research performed in this thesis will serve as a platform to explore the possibility of MTDL as potential therapeutic solutions to diseases of complex etiologies such as chronic pain. It will also serve as a starting point to exploring bifunctional VLS as a way to screen large chemical libraries for MTDLs.

Opioids

Mu Opioid Receptor

Nav1.7

Voltage Gated Sodium Ion Channel

Multi target directed ligands

Bifunctional compounds

PZM21

Aryl Sulfonamide

Structure Activity Relationship Studies

Bifunctional Virtual Ligand Screening

Rôle de la néoglucogenèse intestinale et des récepteurs mu-opioïdes dans les effets bénéfiques du by-pass gastrique chez la souris / Role of intestinal gluconeogenesis and mu-opioid receptors in the metabolic benefits of gastric bypass in mice

Barataud, Aude

09 December 2014

Le by-pass gastrique Roux-en-Y (BPG) est une chirurgie de l'obésité qui induit des améliorations spectaculaires de l'homéostasie glucidique indépendamment de la perte de poids. Un mécanisme proposé pour expliquer ces améliorations est une augmentation de la production intestinale de glucose (PIG) qui induit des effets bénéfiques sur l'organisme (satiété, amélioration de la sensibilité hépatique à l'insuline). Cette augmentation de la PIG, retrouvée chez la souris ayant subi un BPG simplifié, est également responsable des effets bénéfiques des régimes enrichis en protéines via l'inhibition des récepteurs mu-opioïdes (RMO) par les peptides. Nous avons donc testé l'hypothèse selon laquelle les effets bénéfiques du BPG dépendraient d'une inhibition des RMO par les protéines alimentaires et nous avons également testé le rôle causal de la PIG dans ces améliorations métaboliques. Pour cela, nous avons réalisé un by-pass duodéno-jéjunal (BDJ), ie un BPG sans restriction gastrique, chez des souris sauvages (WT), des souris invalidées pour le gène du RMO (MOR-/-) et des souris dépourvues de PIG (I-G6pc-/-). Chez les souris obèses, Le BDJ induit une forte perte de poids (–30%), en partie expliquée par une malabsorption lipidique, ainsi qu'une amélioration des paramètres glucidiques dépendante de cette perte de poids. Au contraire, chez la souris de poids normal, le BDJ n'induit ni perte de poids ni malabsorption mais améliore la tolérance au glucose. Les effets sont les mêmes chez les souris WT, MOR-/- et I-G6pc-/- ce qui montre que les récepteurs mu-opioïdes et la PIG ne semblent pas avoir de rôle causal dans les améliorations du métabolisme énergétique et glucidique après BDJ / Roux-en-Y gastric bypass procedure (GBP) is an obesity surgery that induces dramatic glucose homeostasis improvements independently of weight loss. A proposed mechanism to explain these glucose homeostasis improvements is an increase in intestinal glucose production (IGP) that induces beneficial effects on metabolism (satiety, improved liver insulin sensitivity). This increase in IGP is found in mice that have undergone a simplified GBP and is also responsible for the beneficial effects of protein-enriched diets through the inhibition of mu-opioid receptors (MOR) by alimentary peptides. We therefore hypothesized that the beneficial effects of GBP could depend on MOR inhibition by dietary proteins and we also tested the causal role of IGP in these metabolic improvements. For this purpose, we performed a duodenal-jejunal bypass surgery (DJB), ie GBP without gastric restriction, in wild-type mice (WT), in mice lacking MOR gene (MOR-/-) and in mice lacking IGP (IG6pc-/-). In obese mice, DJB induced a rapid and substantial weight loss (-30%), partly explained by fat malabsorption, and weight loss-dependent improvements of glucose homeostasis. In contrast, in the non-obese mice, DJB did not induce weight loss nor malabsorption but improved glucose tolerance. Effects were similar in WT, MOR-/- and I-G6pc-/- mice showing that mu-opioid receptors and IGP did not appear to have a causal role in glucose and energy metabolism improvements after DJB

Chirurgie bariatrique

By-pass gastrique

By-pass duodéno-jéjunal

Obésité

Diabète de type II

Récepteurs mu-opioïdes

Néoglucogenèse intestinale

Malabsorption

Bariatric surgery

Gastric bypass

Duodenal-jejunal bypass

Obesity

Type 2 diabetes

Mu-opioid receptors

Intestinal gluconeogenesis

Malabsorption

571

Rôle et implication du système cannabinoïde dans la modulation périphérique de la douleur inflammatoire et neuropathique

Desroches, Julie

04 1900

Les dérivés de l’opium (opioïdes) et du cannabis (cannabinoïdes) présentent de nombreuses propriétés intéressantes. Suite à l’identification de leurs récepteurs respectifs, diverses stratégies pharmacologiques ont tenté d’exploiter leurs propriétés analgésiques. Le clonage des récepteurs cannabinoïdes CB1 et CB2 a favorisé la découverte de composés endogènes pour ces récepteurs, les endocannabinoïdes, dont les deux plus étudiés sont l’anandamide et le 2-arachidonyl glycérol (2-AG). Cette découverte a également mené à l’identification d’enzymes qui catalysent l’inactivation de ces cannabinoïdes endogènes : une amidohydrolase des acides gras ou FAAH ainsi qu’une monoacylglycérol lipase ou MAGL. Le système cannabinoïde endogène est régulé à la hausse dans une variété de processus pathologiques, tels que les douleurs inflammatoire et neuropathique. Cette augmentation est habituellement interprétée comme une réaction physiologique visant à rétablir l’homéostasie et elle a notamment été observée en périphérie. Les endocannabinoïdes semblent donc agir de façon spécifique à des moments clés dans certains tissus ciblés afin de minimiser les conséquences reliées au déclenchement de ces douleurs. Cette observation est très intéressante d’un point de vue thérapeutique puisqu’elle suggère la possibilité de cibler les enzymes de dégradation des endocannabinoïdes dans le but d’augmenter leurs concentrations locales et d’ainsi prolonger leur action neuromodulatrice. En périphérie, l’activation des récepteurs cannabinoïdes induit des effets antinociceptifs bénéfiques tout en minimisant les effets indésirables souvent associés à leur activation centrale. Nous avons orienté nos travaux vers la modulation périphérique de ce système endogène à l’aide d’inhibiteurs des enzymes de dégradation des endocannabinoïdes afin d’évaluer leur potentiel thérapeutique et d’élucider les mécanismes d’action qui sous-tendent leurs effets dans des modèles animaux de douleurs inflammatoire et neuropathique. Nous avons démontré que cette approche permet de soulager les symptômes associés à ces deux types de douleurs, et ce via les récepteurs CB1 et CB2. Les systèmes cannabinoïde et opioïde présentent des similitudes, dont des localisations similaires le long des voies de la douleur, des mécanismes d’action relayés par des récepteurs couplés aux protéines G et des propriétés pharmacologiques communes telles que l’analgésie. Le système opioïde est impliqué dans les effets antinociceptifs induits par les cannabinoïdes. À l’inverse, le rôle joué par le système cannabinoïde dans ceux induits par la morphine demeure incertain. Nous avons démontré que les effets antinociceptifs périphériques et spinaux produits par la morphine sont diminués chez les souris génétiquement modifiées chez lesquelles l’expression des récepteurs CB1 ou CB2 a été éliminée, laissant supposer un rôle pour ces récepteurs dans les effets de la morphine. Nous avons de plus démontré que la diminution de l'analgésie produite par la morphine dans ces souris n'est pas causée par un dysfonctionnement des récepteurs opioïdes mu (MOP) ni par une régulation à la baisse de ces récepteurs. Nos résultats confirment l'existence d'interactions fonctionnelles entre les systèmes cannabinoïde et opioïde au niveau périphérique et spinal. Ces observations sont prometteuses d’un point de vue thérapeutique puisqu’une modulation périphérique ciblée des niveaux d’endocannabinoïdes et d’opioïdes endogènes permettrait de produire des effets analgésiques bénéfiques potentiellement synergiques tout en minimisant les effets indésirables associés à l’activation centrale de ces systèmes. / Opium (opioids) and cannabis (cannabinoids) derivatives present many interesting properties. Following the identification of their respective receptors, various pharmacological strategies have tried to exploit their analgesic properties. The cloning of cannabinoid CB1 and CB2 receptors has promoted the discovery of endogenous agonists of these receptors named endocannabinoids. The two mostly studied endocannabinoids are anandamide and 2-arachidonoyl glycerol (2-AG). This has also led to the identification of enzymes that catalyze the inactivation of these endogenous cannabinoids: a fatty acid amide hydrolase or FAAH and a monoacylglycerol lipase or MAGL. It is known that the endogenous cannabinoid system is upregulated in a variety of pathological processes, such as inflammatory and neuropathic pain. This increase is usually interpreted as a physiological response to restore homeostasis and it was particularly observed in the periphery. Endocannabinoids seem to act specifically at key moments in targeted tissues to minimize the consequences related to the onset of pain. This observation is very interesting from a therapeutic perspective because it suggests the possibility of targeting the endocannabinoid degrading enzymes in order to increase their local concentrations and thus prolong their neuromodulatory action. At the peripheral level, the activation of cannabinoid receptors induces beneficial antinociceptive effects while minimizing side effects often associated with their central activation. We focused our work on the peripheral modulation of this endogenous system using inhibitors of endocannabinoid degrading enzymes to assess their therapeutic potential and to elucidate the mechanisms of action underlying their effects in animal models of inflammatory and neuropathic pain. We have demonstrated that this approach can relieve the symptoms associated with these two types of pain, through the activation of CB1 and CB2 receptors. The opioid and cannabinoid systems have similarities, including comparable locations along the pain pathways, mechanisms of action relayed by G protein-coupled receptors and common pharmacological properties such as analgesia. The opioid system is involved in the antinociceptive effects induced by cannabinoids. In contrast, the participation of the cannabinoid system in those induced by morphine remains uncertain. We have demonstrated that peripheral and spinal antinociceptive effects induced by morphine are reduced in genetically modified mice in which the expression of CB1 and CB2 receptors was eliminated, suggesting a role for these receptors in the effects of morphine. We have further demonstrated that the decrease in morphine-induced analgesia in these mice is not caused by a malfunction of the mu opioid receptors (MOP) or by a down-regulation of these receptors. Our results confirm the existence of functional interactions between cannabinoid and opioid systems at the peripheral and spinal levels. These findings are promising from a therapeutic perspective since a targeted modulation of the levels of endocannabinoids and endogenous opioids would induce potentially synergistic beneficial analgesic effects while minimizing side effects associated with the central activation of these systems.

2-arachidonylglycérol

anandamide

récepteurs cannabinoïdes

monoacylglycérol lipase

amidohydrolase des acides gras

morphine

récepteurs opioïdes mu

douleur inflammatoire

douleur neuropathique

2-arachidonoylglycerol

anandamide

cannabinoid receptors

monoacylglycerol lipase

fatty acid amide hydrolase

mu opioid receptors

inflammatory pain

neuropathic pain