Neuropeptide release in the rat dorsal horn in models of persistent pain : effects of opioids /

Afrah, Abdullahi Warsame,

January 2002

Diss. (sammanfattning) Stockholm : Karol. inst., 2002. / Härtill 6 uppsatser.

Structural and pharmacological studies of synthetic and endogenous opioid receptor ligands

Patel, Dinesh

January 1992

The interaction of a diverse set of opioid alkaloids and peptides with various opioid receptors has been examined using biochemical and pharmacological techniques. Structural information on the compounds was obtained from single crystal X-ray diffraction and nuclear magnetic resonance studies, and modelled by computational methods. The introduction of a dithiocarbazate moiety into the 7a-position of a bridged thebaine was shown to afford a degree of μ selectivity in this class of nonselective compounds. X-ray diffraction analysis of this compound and comparison with the structure of [Met5]enkephalin showed the importance of the sulphydryl moiety. The conformation of [Leu5]enkephalin, in which the amino acid methionine is replaced by leucine, at the same receptor is unlikely to be similar. A series of morphinan derivatives which had been developed as μ-antagonists were evaluated. Substitution patterns of the morphinan ring nucleus and their effect upon activity were examined. X-ray analysis of several key compounds was performed. Unexpectedly a 3-hydroxymorphinan-6-one analogue showed an ability to differentiate apparently similar opioid Kreceptors. The implications in terms of K-receptor subtypes are discussed. The opioid receptor binding characteristics of structurally diverse K-receptor ligands were examined in two different buffer systems. Electrostatic modelling of the K-ligands, based upon crystal structure coordinates, was performed. From electrostatic potential maps a requirement for ligands acting at Kreceptors is postulated. Solution conformations of the endogenous K-ligand, dynorphin A(1-8), were determined by nuclear magnetic resonance studies and compared with the wo preferring [Leu5]enkephalin. Models were proposed based upon dihedral angles determined from HCtl-NH coupling constants, amide proton-deuteron exchange and amide proton temperature coefficient data. Candidate conformations were shown to be stable under dynamic simulation conditions. Electrostatic modelling of a chosen dynorphin An-8) conformation gave results comparable with the observed electrostatic model of the K-ligands. The proposed model is discussed in terms of its suitability as a retro-model for the active site ofthe K-opioid receptor.

615.1

Développement de nanomédicaments innovants pour vaincre la douleur : une alternative à la morphine / A new painkiller nanomedicine to by-pass the blood-brain-barrier and the use of morphine

Feng, Jiao

14 December 2018

Les neuropeptides endogènes chez l’homme, tels que les enképhalines et endomorphines, ont un potentiel thérapeutique considérable dans le traitement de la douleur. Ils agissent en activant les récepteurs opioïdes qui sont très largement distribués dans le système nerveux central ainsi que dans plusieurs tissus périphériques. Ces neuropeptides présentent, cependant, un certain nombre d’inconvénients qui limitent de manière importante leur efficacité thérapeutique. Tout d’abord, en raison de leur hydrophilie, ils ne passent pas la barrière sang/système nerveux, ce qui limite leur accès aux récepteurs opioïdes. De plus, ils présentent un temps de demi-vie plasmatique relativement court du fait d’une métabolisation rapide. Enfin, pour être efficaces, ces neuropeptides devraient résister à la protéolyse dans le système circulatoire et être suffisamment hydrophobes pour traverser ces barrières hémato-nerveuses.Le but de la thèse a consisté à créer de nouveaux nanomédicaments à base d’endorphines pour vectoriser et combattre la douleur de manière efficace.. Dans ce but, a été établi une liaison chimique covalente, enzymatiquement clivable (ester ou amide), entre le squalène (SQ, un lipide naturel et biocompatible) et le neuropeptide. Ce couplage donne lieu à des prodrogues qui ont la capacité de s'auto-assembler en nanoparticules (NPs) dans l'eau sans l’aide d'un agent tensio-actif. D’une manière générale, cette technologie présente de nombreux avantages tels qu’un taux de charge élevé en principe actif, une protection efficace de celui-ci vis-à-vis de la métabolisation et l’absence de phénomène de « burst release ».Durant ce travail de thèse, nous avons pu montrer pour la première fois que les Leu-enképhalines (LENK) pouvaient devenir efficaces pharmacologiquement une fois couplées au squalène, via une liaison amide (Am), ou via un bras espaceur, tel que le dioxycarbonyl (Diox), ou le diglycolate (Dig). Les prodrogues résultant de ce couplage ont toutes montré des propriétés d’auto-assemblage en milieu aqueux. Cette nanoformulation à base de squalène a permis, d’une part de protéger la LENK de la métabolisation rapide dans le plasma et d’autre part, de lui conférer un effet anti-hyperalgésique significatif dans un modèle de douleur inflammatoire induite chez le rat par la carragénine (test de Hargreaves). Il est important de souligner que cet effet anti-hyperalgésique a duré 3 fois plus longtemps qu’avec la morphine. Un prétraitement avec un antagoniste des récepteurs opioїdes imperméable à la BHE, comme la méthylnaloxone a complètement antagonisé l’effet anti-hyperalgésique des nanoparticules de LENK-SQ, démontrant ainsi que celles-ci agissent via les récepteurs opioïdes périphériques. De plus, l’étude de biodistribution de NPs LENK-SQ fluorescentes a montré une forte accumulation des celles-ci au niveau de la patte œdémateuse, mais aussi dans le foie, la rate et les poumons alors qu’aucun signal n’a pu être détecté au niveau cérébral, ce qui confirme bien l’effet périphérique de ces nanoparticules. Enfin, des études toxicologiques ont montré que malgré l’accumulation des NPs dans le foie, les taux d’aspartate transaminase (AST) et alanine transaminase (ALT) n’ont pas augmenté garantissant ainsi l’innocuité des NPs LENK-SQ après leur injection i.v. Cette étude représente une approche innovante et prometteuse permettant une distribution ciblée du neuropeptide endogène LENK dans les tissus œdémateux pour soulager efficacement la douleur inflammatoire. / Enkephalin is an endogenous pentapeptide producing potent analgesia by activating opioid receptors located on central and peripheral neuronal cell membranes. However, its clinical use has historically been limited due to pharmacokinetic issues, including restricted plasma stability and blood brain barrier impermeability. The aim of this project is to create a new enkephalin-based nanomedicine targeting pain, using biocompatible and biodegradable materials for drug delivery and targeting purposes, such as squalene (squalenoylation nanotechnology). This nanotechnology presents a new concept with numerous advantages in comparison with the conventional nanocarriers, such as high drug loading and absence of “burst release”. Here, we show for the first time, that the rapidly metabolized Leu-enkephalin (LENK) neuropeptide may become pharmacologically efficient owing to its simple conjugation with the squalene (SQ) using three different chemical linkers, i.e., dioxycarbonyl (Diox), diglycolate (Dig), or amide bond (Am). The resulting prodrugs were able to self-assemble in nanoparticles in aqueous media. This new squalene-based nanoformulation prevented rapid plasma degradation of LENK and conferred to the released neuropeptide a significant anti-hyperalgesic effect in a carrageenan-induced paw edema model in rats (Hargreaves test). It should be stressed that this effect lasted 3 times longer than morphine. Pretreatment with brain impermeant opioid receptor antagonist naloxone methiodide (Nal-M) reversed the nanoparticles induced anti-hyperalgesia, indicating that LENK-SQ NPs acted through peripherally located opioid receptors. Moreover, the biodistribution of DiD-fluorescently labeled LENK-SQ NPs showed a strong accumulation of the fluorescence within the inflamed paw as well as in the liver, spleen, and lung, while no signal could be detected in the brain, confirming the peripheral effect of LENK-SQ NPs. Toxicological studies showed that despite nanoparticles accumulation in the liver, the levels of aspartate transaminase (AST) and alanine transaminase (ALT) were not increased after i.v. injection of LENK-SQ NPs, highlighting thus their safety. This study represents a novel drug targeting approach, allowing the specific delivery of LENK neuropeptide into inflamed tissues for pain alleviation.

Nanomédecine

Leu-Enképhaline

Squalène

Hyperalgésie

Douleur inflammatoire

Récepteurs opioïdes périphériques

Nanomedicine

Leu-Enkephalin

Squalene

Hyperalgesia

Inflammatory pain

Peripheral opioid receptors

Význam opioidních a TLR-4 receptorů v mechanismu působení opioidů na srdeční svalové buňky / Evaluation of opioid and TLR-4 receptors in the mechanism of opioid effects on heart muscle cells

Biriczová, Lilla

January 2020

It has been reported that opioid receptor activation mimics ischemic preconditioning, which may protect the heart from the development of infarction. Toll-like receptor 4 (TLR-4) during infarction stimulates cytokine production leading to inflammation and injury of the heart tissue. Our aim was to study the effect of morphine in vitro on the viability and oxidative state of H9c2 cells (rat cardiomyoblasts) and the role of TLR-4 during oxidative stress. Our experiments showed that pretreatment with morphine before tert-butylhydroperoxide (t-BHP)-, 2,2'-bipyridyl (BP)- and lipopolysaccharide (LPS)-induced oxidative stess had protective effect on the viability of H9c2 cells and markedly reduced the production of reactive oxygen species (ROS). The protective effect of morphine was diminished after naloxone treatment, which confirms the role of opioid receptors in preconditioning. TLR-4 inhibition by TAK-242 pretreatment and silencing TLR-4 by RNA interference resulted in a partial increase in cell viability but significant attenuation of ROS production after t-BHP and BP treatment. The action of LPS was reduced in response to TLR-4 silencing. Interestingly, naloxone pretreatment and suppression of TLR-4 markedly alleviated oxidative stress and resulted in a significant improvement of cell viability. We...

Développement d'un biosenseur BRET permettant le criblage de drogues qui causent l'activation de canaux Kir3 via les récepteurs couplés aux protéines G

Richard-Lalonde, Mélissa

08 1900

Les récepteurs couplés aux protéines G forment des complexes multimériques comprenant protéines G et effecteurs. Nous cherchons à caractériser de tels complexes comprenant les récepteurs opioïdes delta (DOR) et les canaux Kir3, qui nous sont d’intérêt vu leur implication dans l’analgésie des opioïdes. Des expériences d’immunopurification, de BRET et de liaison GTPgS ont été réalisées à l’intérieur de cellules HEK293 transfectées. Les canaux Kir3 ont été co-immunopurifiés avec les DOR, suggérant une interaction spontanée entre récepteur et effecteur. Des essais BRET ont corroboré que l’interaction était présente dans des cellules vivantes et nous ont permis d’identifier une interaction spontanée et spécifique entre DOR/Gg et Gg/Kir3, indiquant leur coexistence en un même complexe. Puisque l’activation du récepteur implique la présence de changements conformationnels à l’intérieur de celui-ci, nous étions intéressés à vérifier si l’information conformationnelle circule à partir du récepteur lié au ligand jusqu’à l’effecteur en aval. Ainsi, nous avons déterminé l’effet de différents ligands sur le signal BRET généré par les paires suivantes : DOR/Gbg, DOR/Kir3 et Kir3/Gbg. Nous avons constaté une modulation de l’interaction DOR/Gbg et Gbg/Kir3 suivant l’ordre d’efficacité des ligands à stimuler la protéine G, ce que nous n’avons pas observé entre DOR et Kir3. Donc, nous concluons que l’information conformationnelle circule du récepteur au canal Kir3 via la protéine Gbg. Ces résultats nous ont permis de développer un biosenseur BRET (EYFP-Gg2/Kir3.1-Rluc) qui pourrait être utilisé dans le criblage à haut débit afin de détecter de nouvelles molécules ayant une grande efficacité à activer les canaux Kir3. / G protein-coupled receptors form multimeric complexes comprising G protein and effectors. We want to characterize such complexes comprising delta opioid receptors (DOR) and Kir3 channels, which interest us due to their involvement in opioid analgesia. Immunopurification, BRET and GTPgS binding experiments were done in transfected HEK293 cells. Kir3 channels were co-immunopurified with DOR, implying a spontaneous interaction between the receptor and effector. BRET assays corroborated the presence of this interaction in living cells and allowed us to identify a spontaneous and specific interaction between DOR/Gg and Gg/Kir3, indicating their co-existence within the same complex. Since the activation of the receptor implies it undergoes conformational changes, we were interested in evaluating if the conformational information flows from the ligand-bound receptor until the downstream effector. Hence, we determined the effect of different ligands on the BRET signal that was generated by the following pairs: DOR/Gbg, DOR/Kir3 and Kir3/Gbg. We noticed a modulation of the DOR/Gbg and Gbg/Kir3 interactions that followed the order of efficacy of the ligands to activate the G protein, which we did not observe between DOR and Kir3. Therefore, we concluded that the conformational information flows from the receptor to the Kir3 channel via the Gbg protein. These results allowed us to develop a BRET biosensor (EYFP-Gg2/Kir3.1-Rluc), which could be used in high throughput screening to detect new molecules that activate Kir3 channels with high efficacy.

complexes multimériques

récepteurs opioïdes delta

sélectivité fonctionnelle

HEK293

conformations multiples

multimeric complexes

functional selectivity

delta opioid receptors

HEK293

multiple conformations

Etude des interactions fonctionnelles entre récepteurs à peptide RF-amide et caractérisation de ligands bifonctionnels des récepteurs mu opioïde et NPFF / Functional interactions between RF-amide receptors and characterisation of mu opioid and NPFF receptors dual acting drugs

Drieu la Rochelle, Armand

12 April 2018

Les opiacés demeurent des molécules incontournables dans le traitement des douleurs moyennes à sévères. Si leur efficacité dans le traitement de la douleur aiguë est incontestable, leur utilisation chronique est responsable de nombreux effets indésirables comprenant une hypersensibilité à la douleur et une tolérance à leurs effets analgésiques. Une partie de ces effets secondaires résulteraient de l’activation de systèmes anti-opioïdes endogènes, comme les neuropeptides RF-amide, dont des études précédentes suggèrent une complémentarité de fonctionnement dans la modulation de la douleur. Le premier axe de travail de cette thèse fut de développer les outils moléculaires afin d’étudier la possibilité d’interactions fonctionnelles et d’hétérodimérisation de ces récepteurs, en particulier GPR103 et NPFF1R. Nous avons ainsi pu générer et caractériser des lignées cellulaires exprimant les différents récepteurs à peptide RF-amide avec un fluorophore fusionné à leur extrémité amino-terminale. En parallèle, nous avons pu développer au cours d’une collaboration fructueuse avec deux équipes de chimistes un ligand à dualité d’action, agoniste opioïdergique et antagoniste des récepteurs NPFF1R et NPFF2R. Chez la souris, nous avons montré que l’administration sous-cutanée de ce composé produit une analgésie longue durée, qui n’est pas atténuée par le développement de tolérance analgésique ou d’hyperalgésie après une semaine d’administration quotidienne. Le syndrome de sevrage, précipité par la naltrexone est plus faible après l’administration chronique de ce composé qu’avec l’agoniste opioïdergique de référence. De plus, grâce à ses caractéristiques d’agoniste biaisé sur le récepteur MOR, cette molécule induit une plus faible dépression respiratoire chez la souris. / Opioid analgesics continue to be the cornerstones for treating moderate to severe pain. However, upon chronic administration, their efficiency is limited because of prominent side effects, such as tolerance and dependence. One hypothesis for the occurrence of these side effects is that the chronic stimulation of the opioid system may trigger its endogenous counterparts, anti-opioid systems, producing hyperalgesia and analgesic tolerance. Previous data from our lab and others suggest that RF-amide peptide receptors can modulate pain signalling through cross-interactions. We developed cell lines expressing fluorescent RF-amide receptors for the study of functional crosstalk and heterodimerization between RF-amide peptide receptors, i.e. GPR103 and NPFF1R. Through a productive collaboration with two teams of chemists, we identified and characterized multitarget peptidomimetic compounds that combined G protein-biased agonism and NPFFR antagonism. In accordance with in vitro results, we observed that acute subcutaneous administration of this compound produced long-lasting antinociceptive effects with less respiratory depression in mice. No hypersensitivity nor analgesic tolerance developed after chronic administration. Altogether, this molecule showed potent antinociceptive effect with limited side effects upon acute and chronic administration.

RCPG

Récepteurs RF-amide

Récepteurs opioïdes

Interaction fonctionnelle

Douleur

Tolérance analgésique

GPCR

RF-amide receptors

Functional cross-talk

Opioid receptors

Pain

Analgesic tolerance

572.8

615.7

Mu opioid receptors in the habenula : dissecting reward and aversion in addiction / Récepteurs Mu aux opioïdes dans l'habénula : récompense et/ou aversion dans l'addiction

Boulos, Laura-Joy

19 December 2017

Les récepteurs mu aux opioïdes (MORs) jouent un rôle central dans l’addiction et ce majoritairement via le contrôle qu’ils exercent sur les phénomènes de récompense. Les effets des MORs sur le système de récompense sont généralement attribués à leur expression dans le circuit mésocorticolimbique. Les MORs sont toutefois exprimés dans d’autres régions du cerveau, notamment dans une petite structure cérébrale épithalamique qui exprime la plus forte densité de MORs : l’habénula médiane (MHb). Le rôle de cette population spécifique de récepteurs n’a jamais été exploré, malgré l’implication fortement suggérée dans la littérature de l’habénula dans l’addiction et les processus de récompense/aversion sous-jacents. Nous avons donc généré un modèle de souris knockout conditionnel chez lesquelles nous supprimons les MORs uniquement dans l’habénula et nous les avons soumis à des tests comportementaux dans le but d’évaluer les fonctions de ces récepteurs et leur impact sur le comportement avec un focus sur les processus aversifs, cognitifs et récompensant. Nos résultats révèlent que les récepteurs mu que nous supprimons dans l’habénula limitent l’aversion somatique et affective mais ne modulent ni les réponses locomotrices, analgésiques et de récompense à la morphine, ni les fonctions cognitives que nous avons testées. Nous identifions donc pour la première fois une population de MORs dans l’habénula qui freinent l’aversion et nous suggérons par là-même que les récepteurs mu de l’habénula pourraient être cruciaux dans le stage «sevrage aversif» des cycles d’addiction. / Mu opioid receptors (MORs) have been extensively studied for their addictive properties that are thought to operate through the control of reward processes. While the importance of MORs in reward is generally attributed to their presence in the mesocorticolimbic circuitry, their role in the medial habenula (MHb), the structure in which MORs are most densely expressed, remains unexplored to date. This is quite surprising given the increasing literature on the habenula’s role in addiction as well as reward/aversion processes. Here we generated a conditional knockout mouse model that lacks MORs solely in the MH band we investigated the contribution of habenular MORs in brain functions and behavioural out comes with emphasis on reward, aversion and cognition. While the performance of our mutant model did not differ in locomotor, analgesic and reward responses to morphine norincognitive tasks compared to control mice, we uncovered a novel role for MORs in aversive states.This is the first report demonstrating that MORs control both somatic and affective aversion specifically at the level of the MHb. Habenular MORs could thus be crucial to the aversive with drawal stage of addiction cycles that is thought to increase craving and prevent success in quitting.

Récepteurs opioïdes mu

Souris knockout conditionnelles

Habénula

Recompense

Aversion

Cognition

Mu opioid receptors

Knock out mice

Habenula

Reward

Aversion

Cognition

572.8

Efeito analgésico periférico do tramadol em modelo de dor pós-operatória em ratos / Peripheral analgesic effect of tramadol in a postoperative pain model in rats

Oliveira Junior, José Oswaldo de

24 February 2016

INTRODUÇÃO: Tramadol é conhecido como um fármaco analgésico de ação central utilizado no tratamento de dores de intensidades moderada a forte. Efeito analgésico local já foi demonstrado. É, em parte, semelhante ao efeito anestésico local, mas outros mecanismos permanecem desconhecidos. O papel de receptores opioides periféricos na analgesia do tramadol na dor pós-operatória não é conhecido. Neste estudo, foi estudado o papel dos receptores opioides no efeito analgésico local do tramadol em modelo de dor por incisão plantar. MÉTODOS: Ratos machos jovens foram submetidos à incisão plantar e no primeiro dia pós-incisão foram divididos em quatro grupos: Grupo IP I-SF/SF - 50 uL de solução de NaCl 0,9% foram injetados na região plantar da pata posterior homolateral à incisão e, 15 minutos depois, novamente injetada a mesma quantidade de solução; Grupo IP II-SF/T_homo - 50 uL de NaCl 0,9% foram injetados na região plantar da pata homolateral e, 15 minutos depois, injetados 50 µL solução contendo 5 mg tramadol; Grupo IP III-SF/T_contra -50 uL de NaCl 0,9% foram injetados na região plantar da pata contralateral e, 15 minutos depois, 50 uL de solução contendo 5 mg de tramadol; Grupo IP IV-Nal/T_homo - 50 uL de solução contendo 200 ug de naloxona foram injetados na pata homolateral e, 15 minutos depois, 50 uL de solução contendo 5mg de tramadol foi injetada. Antes de receberem as injeções, os limiares de retirada da pata por estímulo mecânico produzido por analgesímetro eletrônico de von Frey foram medidos, e, depois da administração dos fármacos, os limiares de retirada foram avaliados nos tempos 15, 30, 45 e 60 minutos após a administração dos fármacos. O mesmo procedimento foi utilizado no segundo dia pós-incisão. As expressões proteicas dos receptores opioide ? (DOR) e µ (MOR) foram avaliadas usando técnica de immunoblotting de gânglios de raízes dorsais homolaterais (L3, L4, L5 e L6) de grupos de animais sem incisão e após 1, 2, 3 e 7 dias de animais submetidos à incisão plantar. RESULTADOS: A incisão plantar gerou marcada hiperalgesia mecânica que foi revertida por tramadol intraplantar nos dois dias. O tramadol intraplantar em pata contralateral não antagonizou a hiperalgesia mecânica, a naloxona antagonizou parcialmente o efeito analgésico do tramadol no primeiro dia pós-incisão, e antagonizou completamente no segundo dia pós-incisão. A expressão proteica de DOR aumentou no 2º, 3º e 7º dias pós-incisão, a expressão de MOR não se modificou. CONCLUSÕES: O tramadol apresentou efeito analgésico local após estímulo mecânico e esse efeito foi antagonizado por naloxona no segundo dia pós-incisão. A expressão de DOR aumentou após a incisão plantar / BACKGROUND: Tramadol is known as a central acting analgesic drugused for the treatment of moderate to severe pain. Local analgesic effect was already demonstrated. It is in part due to local anesthetic-like effect, but other mechanisms remain unclear. The role of peripheral opioid receptors in the local analgesic effect in postoperative pain is not known. In this study, we examined the role of peripheral opioid receptors in the local analgesic effect of tramadol in the plantar incision pain model. METHODS: Young male Wistar rats were submitted to plantar incision and in the first postoperative day (POD1) were divided into four groups:IP I-SF/SF,50 uL of 0.9% NaCl solution were injected in the plantar aspect of the homolateral hindpaw and again after 15 minutes; IP II-SF/T_homo, 50 uL of 0.9% NaCl solution were injected in the plantar aspect of the homolateral hindpaw and, 15 minutes later, 50 µL of solution containing 5 mg tramadol were injected in the same hindpaw; IP III-SF/T_contra, 50 uL of 0.9% NaCl were injected in the plantar aspect of the contralateral hindpaw and, 15 minutes later, 50 uL of solution containing 5 mg tramadol were injected in the same hindpaw; IP IVNal/T_homo, 50 uL of naloxone (200 ug) solution were injected in the homolateral hindpaw and 15 minutes later 50 µL of solution containing 5 mg tramadol were injected. Before receiving the assigned drugs, baseline withdrawal thresholds for mechanical hyperalgesia using electronic von Frey were measured, then, after receiving the assigned drugs, withdrawal thresholds were measured at 15, 30, 45 and 60 min after drug injection. The same procedure was repeated in POD2. u opioid receptor (MOR) and opioid receptor (DOR) protein expressions were evaluated using immunoblotting after removal of ipsilateral dorsal root ganglia (L3, L4, L5 and L6) in groups of rats non submitted to plantar incision and 1, 2, 3 and 7 days after incision. RESULTS: Plantar incision led to marked mechanical hyperalgesia that was reversed with intraplantar tramadol in both days. Contralateral tramadol did not affect mechanical hyperalgesia and naloxone antagonized partially intraplantar tramadol in POD1, and antagonized completely in POD2. DOR expression in DRGs increased in POD2, POD3 and POD7, MOR expression did not change. CONCLUSIONS: Tramadol presented local analgesic effect after mechanical stimuli and this effect was antagonized by naloxone in the second post incision day. DOR increased expression after plantar incision

Dor nociceptiva

Dor pós-operatória

Limiar da dor

Naloxona

Naloxone

Nociceptive pain

Opioid receptors

Pain thresholds

Postoperative pain

Ratos

Rats

Receptores opioides

Tramadol

Tramadol

Αλληλεπιδράσεις των επταελικοειδών υποδοχέων με διάφορες πρωτεΐνες. Χαρακτηρισμός νέων σηματοδοτικών μονοπατιών / Protein-protein interactions of the heptahelical receptors. Identification of new signaling pathways

Παπακωνσταντίνου, Μαρία-Παγώνα

07 April 2015

Οι οπιοειδείς υποδοχείς (OR), μ, δ, κ και NOP, είναι μέλη των επταελικοειδών υποδοχέων που συζεύγνυνται με G πρωτεΐνες (7ΤΜ ή GPCR), οι οποίοι αποτελούν τη μεγαλύτερη υπεροικογένεια υποδοχέων και έναν από τους κύριους φαρμακολογικούς στόχους λόγω της υψηλής φυσιολογικής τους σημασίας. Οι OR ρυθμίζουν μια ποικιλία φυσιολογικών αποκρίσεων στο νευρικό σύστημα, με κυριότερη την αναλγησία. Τα οπιοειδή φάρμακα είναι τα πιο ισχυρά και αποτελεσματικά αναλγητικά έναντι στον οξύ πόνο, όμως η παρατεταμένη χρήση τους οδηγεί σε φαινόμενα ανοχής και εξάρτησης. Γι’ αυτό υπάρχει έντονο ενδιαφέρον στην αποσαφήνιση των μηχανισμών που εμπλέκονται στα φαινόμενα αυτά προκειμένου να σχεδιαστούν πιο αποτελεσματικά φάρμακα χωρίς τέτοιες παρενέργειες. Η σηματοδότηση των οπιοειδών υποδοχέων γίνεται κυρίως μέσω της ενεργοποίησης των Gi/o πρωτεϊνών που με τη σειρά τους ρυθμίζουν κατάλληλους τελεστές. Πέρα όμως από αυτούς τους κλασσικούς αλληλεπιδρώντες εταίρους οι OR έχουν την ικανότητα να αλληλεπιδρούν και με πολλές άλλες πρωτεΐνες κυρίως μέσω των περιοχών της τρίτης ενδοκυτταρικής τους θηλιάς (i3L) και του καρβοξυτελικού τους άκρου (CT) (Georgoussi et al., 2006- Georgoussi, 2008- Georgoussi et al., 2012). Οι αλληλεπιδράσεις αυτές επηρεάζουν όχι μόνο την σηματοδότηση των OR αλλά και την εν γένει εύρυθμη λειτουργία τους. Μια σημαντική πρωτεϊνική οικογένεια που ελέγχει τη μεταγωγή σήματος από τις G πρωτεΐνες βρέθηκε να είναι οι πρωτεΐνες Ρυθμιστές της κυτταρικής Σηματοδότησης μέσω G πρωτεϊνών ή RGS πρωτεΐνες (Regulators of G protein signaling, RGS). Ο πρωταρχικός τους ρόλος είναι η αλληλεπίδραση τους με τις Gα υπομονάδες των G πρωτεϊνών και η επιτάχυνση της υδρόλυσης του GTP από τις τελευταίες οδηγώντας στη μείωση της σηματοδότησης των GPCR. Μέλη της οικογένειας των RGS πρωτεϊνών είχε δειχθεί ότι πέρα από τις Gα πρωτεΐνες αλληλεπιδρούν επίσης με υποδοχείς GPCR, τελεστές αλλά και με άλλες ρυθμιστικές πρωτεΐνες, προσδίδοντας τους έναν ιδιαίτερο οργανωτικό ρόλο στη λειτουργία του κυττάρου και καθιστώντας τις RGS πρωτεΐνες μόρια υψηλού φαρμακολογικού ενδιαφέροντος. Παρελθόντα πειράματα in vitro συγκατακρήμνισης, του εργαστηρίου Κυτταρικής Σηματοδότησης και Μοριακής Φαρμακολογίας, με τη χρήση GST-χιμαιρικών πεπτιδίων των καρβοξυτελικών άκρων των μ-OR και δ-OR (μ-CT και δ-CT αντίστοιχα) και της τρίτης ενδοκυτταρικής θηλιάς του δ-OR (δ-i3L), έδειξαν ότι η RGS4, ένα μέλος της B/R4 υποοικογένειας, αλληλεπιδρά και με τους δυο υποδοχείς στις περιοχές αυτές (Georgoussi et al., 2006- Leontiadis et al., 2009). Η αλληλεπίδραση της RGS4 στα καρβοξυτελικά άκρα των υποδοχέων αυτών γίνεται στην περιοχή που σχηματίζει μια 8η αμφιπαθική α-έλικα (έλικα VIII), σημείο επαφής των OR και για άλλες πρωτεϊνικές αλληλεπιδράσεις όπως αυτή των STAT5A/B ((Mazarakou and Georgoussi, 2005- Georganta et al., 2010), της σπινοφιλίνης (Fourla et al., 2012) και άλλων πρωτεϊνών (Georgoussi et al., 2012). Βρέθηκε επίσης ότι η RGS4 είναι αρνητικός ρυθμιστής της κυτταρικής σηματοδότησης των μ-OR και δ-OR (Georgoussi et al., 2006- Leontiadis et al., 2009). Τέλος, αποδείχθηκε για πρώτη φορά ότι η RGS4 παίξει το ρόλο «μοριακού φίλτρου» καθοδηγώντας τους μ-OR και δ-OR να αλληλεπιδράσουν με συγκεκριμένο διαφορετικό υποπληθυσμό Gα υπομονάδων των G πρωτεϊνών (Leontiadis et al., 2009). Καμία πληροφορία για τον ρόλο των RGS πρωτεϊνών δεν υπάρχει για τον κ-OR. Για τον λόγο αυτό σκοπός της παρούσας διατριβής ήταν να ελέγξουμε αν οι RGS πρωτεΐνες της Β/R4 υποοικογένειας αλληλεπιδρούν με τον κ-OR και αν ναι, ποιος είναι ο ρόλος τους στη σηματοδότηση του κ-OR και των G πρωτεϊνών με τις οποίες ο τελευταίος συζεύγνυται. Τα αποτελέσματά μας έδειξαν ότι ο κ-OR μπορεί να αλληλεπιδράσει και με την RGS4 και με την RGS2 τόσο in vitro όσο και in vivo. Η δημιουργία GST-χιμαιρικών πεπτιδίων του καρβοξυτελικού άκρου του κ-OR (κ-CT) έδειξε ότι η RGS4 αλληλεπιδρά επίσης εντός της έλικας VIII ενώ η RGS2 αλληλεπιδρά με το τελικό μη συντηρημένο άκρο του κ-CT όσο και του δ-CT. Επιπλέον η συνέκφραση της RGS4 ή της RGS2 σε κύτταρα 293F που εκφράζουν τον κ-OR έδειξε ότι και οι δυο RGS πρωτεΐνες προάγουν την επιλεκτική και διαφορική σύζευξη του κ-OR με συγκεκριμένο υποπληθυσμό των Gαi/o υπομονάδων. Σε ότι αφορά τον φυσιολογικό ρόλο των RGS4 και RGS2 στις ελεγχόμενες από τον κ-OR κυτταρικές αποκρίσεις βρήκαμε ότι τόσο η RGS4 όσο και η RGS2 ανέστειλαν την καταστολή της αδενυλικής κυκλάσης που ελέγχει ο κ-OR, αλλά όχι ο δ-OR, με την RGS2 να έχει ισχυρότερη επίδραση στο μονοπάτι αυτό. Επίσης οι RGS4 και RGS2 μείωσαν την ενεργοποίηση των ERK1,2 κινασών που σηματοδοτούσε ο κ-OR. Τέλος, βρήκαμε ότι παρόλο που καμία από τις δυο RGS δεν επηρεάζει την εσωτερίκευση του κ-OR, η RGS4 επιταχύνει την εσωτερίκευση του δ-OR. Τα ευρήματά μας καταδεικνύουν ότι οι RGS4 και RGS2 πρωτεΐνες είναι δυο νέοι αρνητικοί ρυθμιστές στην σηματοδότηση των κ-OR και δ-OR. Εμφανίζουν διαφορικό ρυθμιστικό ρόλο στα σηματοδοτικά μονοπάτια καθενός OR, με ρόλο κλειδί στην καθοδήγηση της σύζευξής τους με τις Gα υπομονάδες και μπορούν να αποτελέσουν ενδιαφέροντες φαρμακολογικούς στόχους για τον έλεγχο της δράσης των οπιοειδών. / Οpioid receptors (OR) (subtypes μ, δ, κ and NOP) belong to the superfamily of the Heptahelical G protein-coupled receptors (7TM or GPCRs), the largest class of receptors in the human genome and common targets for therapeutics. ORs mediate their responses in the nervous system via coupling to members of the Gi/Go proteins to regulate the activity of various effector systems. Opioids are the most potent analgesics but prolonged administration leads to phenomena of tolerance and dependence thus there is a great interest towards understanding of OR signalling in an effort to develop new drugs devoid of adverse effects. Extended observations have demonstrated that the cytoplasmic face of the ORs is critical in mediating their signal through interactions not only with G proteins but also with multiple other proteins. These regulatory proteins play distinct roles in the regulation of the OR signalling, and in the fine tuning of these receptors. Regulators of G protein signalling (RGS) proteins is a class of proteins that modulate G protein signalling events by directly interacting with Gα subunits and accelerating the GTP hydrolysis, thus reducing GPCR signalling towards their effectors. RGS can also interact with many GPCRs, effectors and auxiliary proteins thus playing a key role in the cell functions, making them highly attractive as pharmacological targets (Abramow-Newerly et al., 2006). Our previous in vitro studies have shown that a member of the B/R4 subfamily of RGS proteins such as RGS4 interacts directly with μ-OR and δ-OR within a conserved region in their C-termini (μ-CT and δ-CT), forming a helix VIII, as well as within the δ-third intracellular loop (δ-i3L). RGS4 associates with μ-OR and δ-OR in living cells and forms selective complexes with Gαi/o proteins in a receptor dependent manner. Expression of RGS4 in HEK293 cells attenuated adenylyl cyclase inhibition mediated by μ-OR and agonist-mediated ERK1,2 phosphorylation for both receptors (Georgoussi et al., 2006- Leontiadis et al., 2009), suggesting for the first time that RGS4 is a negative modulator of μ-OR and δ-OR signalling. To deduce whether similar effects also occur for the κ-opioid receptor (κ-ΟR) and define the ability of other members of the B/R4 subfamily of RGS proteins, such as RGS2, to interact with OR we generated fusion peptides encompassing the C-terminus of κ-OR (κ-CT). Results from pull down experiments indicated that RGS2 interacts with the κ-CT, the δ-CT and the δ-i3L but fails to interact with the μ-CT. RGS4-N-terminal domain is responsible for OR interaction. Mapping the sites of RGS2 interaction indicated that RGS2 interacts with the non conserved portion of the C-termini of ORs exhibiting a different docking site as compared to that of RGS4. Co-precipitation studies in living cells indicated that RGS2 and RGS4 associate with κ-ΟR constitutively and upon receptor activation and confer selectivity for coupling with a specific subset of G proteins in an RGS protein dependent manner. Expression of both RGS2 and/or RGS4, in 293F cells attenuated agonist mediated-adenylyl cyclase inhibition for κ-ΟR, but not δ-OR, with RGS2 exhibiting a more robust effect. RGS4 and RGS2 reduced κ-ΟR-mediated ERK1,2 phosphorylation whereas, RGS4 accelerated agonist-induced internalization of the δ-OR but not of the κ-OR. Collectively, our observations demonstrate that RGS2 and RGS4 are novel interacting partners and negative modulators of κ-ΟR and δ-OR signalling. These two RGS proteins display a differential modulatory effect in each signalling pathway tested and play a key functional role by conferring selectivity for both κ-OR and δ-OR coupling with a specific subset of G proteins. Therefore they can be considered as attractive new pharmacological targets to manipulate opioid receptors signalling.

Πρωτεΐνες G

Εσωτερίκευση

Σηματοδότηση

572.6

Kappa and delta opioid receptors

Regulators of G protein signalling

G proteins

Internalization

Signaling

Dependence-induced changes in opioid-receptor gene expression

Johansson, Anna

January 2013

Using drugs such as alcohol and morphine among others can be addictive in some individuals, and progress into a substance abuse disorder. The mesolimbic dopaminergic system (MD-system) is involved in the reward process during the development of drug addiction. The MD-system is critical for survival and affects different behaviors in both man and animal. Neurochemical pathways drive for instance physical activity, food intake, love and reproduction and are part of the natural reward process involved partly in the release of dopamine (DA) into frontal lobes. Within the MD-system opioid receptors throughout the brain are affected by drug intake, and activation of these receptors modulate DA-release in brain regions involved in reward-behavior. The aim of this study was to evaluate gene expression of MOR and DOR within the endogenous opioid system (EO-system) in relation to voluntary physical activity, a natural reinforcer. Further on investigations of the drug alcohol was compared to the natural reinforcer sucrose using voluntary consumption. For both experiments qRT-PCR was used to measure mRNA levels of MOR and DOR from brain areas of interest. We found a small significant up regulation in NAc, PFC and VTA but for DOR in VTA a down regulation in gene expression of physical exercising mice. Additionally these two different genes OPRM1- and the OPRD1- gene are down regulated in VTA and NAc due to alcohol- and sugar-intake. This implicate that the natural reward system and their ORs point in the direction of earlier findings; the opioid receptors have a key role in regulate alcohol intake and the natural rewarding stimuli as food intake.

Neuropeptides

Alcohol

Gene expression

C57/BL6 mice model

Addiction

VTA

Opioid Receptors

Reward

Quantitative RT-PCR

neoropeptider

gene expression

real tids-PCR