Development of a reliable test system for purinergic P2X3 receptors

Tomanová, Šárka

January 2016

Charles University in Prague Faculty of Pharmacy in Hradec Králové Department of Pharmaceutical Chemistry and Drug Control Student: Šárka Tomanová Supervisors: Prof. PharmDr. Martin Doležal, Ph.D., Prof. Dr. Christa Elisabeth Müller Title of diploma thesis: Development of a reliable test system for purinergic P2X3 receptors Purinergic P2X3 receptor is a ligand-gated ionotropic channel that occurs in all mammalian tissues. The highest occurrence has been observed in central and peripheral nervous system and smooth muscles, where P2X3 receptors participate in pathological disorders such as visceral and neurophatic pain, inflammatory reactions and psychiatric disorders. Compounds capable of blocking P2X3 receptor activity could be therefore used as potential drugs for treatment of these states. P2X3 receptor belongs to fast- desensitizing ionotropic channels, which makes the measurement of its activity very difficult. It was described that one point S15V mutation, in which the amino acid serine in a position 15 is replaced by amino acid valine, slows down the desensitization rate and the signal becomes easily measurable. This simple mutation may be used as an effective tool for characterization of insufficiently explored P2X3 receptor. The P2X3 S15V receptor DNA was inserted into retrovirus and,...

Amino acid residues constituting the agonist binding site of the human P2X3 receptor and subunit stoichiometry of heteromeric P2X2/3 and P2X2/6 receptors

Wang, Haihong

30 April 2013

Homotrimeric P2X3 and heteromeric P2X2/3 receptors are present in sensory ganglia and participate in pain perception. In order to develop pharmacological antagonists for these receptors, it is important to clarify which amino acid (AA) residues constitute the agonist binding pouch as well as to learn the stoichiometry of the receptor subunits forming a heteromeric receptor. We expressed the homomeric human (h)P2X3 receptor or its mutants in HEK293 cells and measured the ATP-induced responses by the whole-cell patch-clamp method. For the binding-site mutants, all conserved and some non-conserved AAs in the four nucleotide binding segments (NBSs) of the P2X3 subunit were sequentially replaced by alanine. Especially the positively charged AAs Lys and Arg appeared to be of critical importance for the agonist effects. We concluded that groups of AAs organized in NBSs rather than individual amino acids appear to be responsible for agonist binding at the P2X3 receptor. These NBSs are located at the interface of the three subunits forming a functional receptor. We were also interested to find out, whether two heteromeric receptors (P2X2/3 and P2X2/6), where P2X2 combines with two different partners, have an obligatory subunit stoichiometry of 1:2 or whether the subunit stoichiometry may be variable. For this purpose we used non-functional P2X2, P2X3 and P2X6 subunit-mutants to investigate the composition of heteromeric P2X2/3 and P2X2/6 receptors. The subunit stoichiometry of P2X2/3 and P2X2/6 was found to be 1:2 and 2:1, respectively. Thus, recognitions sites between P2X2 and its partners rather than random association may govern the subunit compositions of the receptor trimers.

ddc:610

Schmerz; Analgesie

Amino acid residues constituting the agonist binding site of the human P2X3 receptor and subunit stoichiometry of heteromeric P2X2/3 and P2X2/6 receptors

Wang, Haihong

28 March 2013

Homotrimeric P2X3 and heteromeric P2X2/3 receptors are present in sensory ganglia and participate in pain perception. In order to develop pharmacological antagonists for these receptors, it is important to clarify which amino acid (AA) residues constitute the agonist binding pouch as well as to learn the stoichiometry of the receptor subunits forming a heteromeric receptor. We expressed the homomeric human (h)P2X3 receptor or its mutants in HEK293 cells and measured the ATP-induced responses by the whole-cell patch-clamp method. For the binding-site mutants, all conserved and some non-conserved AAs in the four nucleotide binding segments (NBSs) of the P2X3 subunit were sequentially replaced by alanine. Especially the positively charged AAs Lys and Arg appeared to be of critical importance for the agonist effects. We concluded that groups of AAs organized in NBSs rather than individual amino acids appear to be responsible for agonist binding at the P2X3 receptor. These NBSs are located at the interface of the three subunits forming a functional receptor. We were also interested to find out, whether two heteromeric receptors (P2X2/3 and P2X2/6), where P2X2 combines with two different partners, have an obligatory subunit stoichiometry of 1:2 or whether the subunit stoichiometry may be variable. For this purpose we used non-functional P2X2, P2X3 and P2X6 subunit-mutants to investigate the composition of heteromeric P2X2/3 and P2X2/6 receptors. The subunit stoichiometry of P2X2/3 and P2X2/6 was found to be 1:2 and 2:1, respectively. Thus, recognitions sites between P2X2 and its partners rather than random association may govern the subunit compositions of the receptor trimers.:Index of contents Introductory remarks „Wissenschaftlicher Anteil des Promovenden an der Publikation“ „Bibliographische Beschreibung“ I. Introduction Pain as a sensory quality Neuronal circuitry for pain processing and sensation in the PNS and CNS Transformation of thermal, mechanical and chemical stimuli into electrical activity by nociceptors; nociceptor-targeted therapeutic approaches Release mechanisms for nucleotides and their fate in the extracellular space Nucleotide receptor-types ATP-sensitive P2 receptors and pain-sensation References II. Scientific background and aims of my thesis ATP binding-sites of P2X3 receptors; subunit composition of P2X2/3 and P2X2/6 heteromeric receptors The aims of the present work III. Publications IV. Summary and conclusions Amino acid residues constituting the agonist binding site of the human P2X3 receptor ATP binding site mutagenesis reveals different subunit stoichiometry of functional P2X2/3 and P2X2/6 receptors „Eigenständigkeitserklärung“ Curriculum vitae Acknowledgements

info:eu-repo/classification/ddc/610

ddc:610

Schmerz; Analgesie

Papel do receptor P2X3 e da ativação da proteína kinase C épsilon dos neurônios nociceptivos periféricos na dor inflamatória / Role of P2X3 receptor and PKC epsilon activation of peripheral nociceptive neurons on inflammatory pain

Prado, Filipe César do

16 August 2018

Orientador: Carlos Amílcar Parada / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-16T13:34:40Z (GMT). No. of bitstreams: 1 Prado_FilipeCesardo_M.pdf: 428700 bytes, checksum: 1f8f2df5d5cae548c5b0d1a6a66947f7 (MD5) Previous issue date: 2010 / Resumo: Enquanto a hiperalgesia inflamatória depende da liberação de prostaglandinas e/ou de aminas simpatomiméticas que sensibilizam os neurônios aferentes primários, nosso grupo demonstrou recentemente que o bloqueio do receptor P2X3 no tecido periférico previne a hiperalgesia induzida pela carragenina.. No entanto, o mecanismo pelo qual a ativação dos receptores P2X3 neuronais contribui para a hiperalgesia inflamatória não está completamente estabelecido. O presente estudo verifica se a ativação do receptor P2X3 dos neurônios aferentes primários contribui para a hiperalgesia mecânica induzida pela prostaglandina E2 ou pela dopamine no tecido periférico. A co-administração de A317491 (60 µg / paw), um antagonista seletivo do receptor P2X3, ou o prétratamento com dexametasona (1 mg / mL / kg), preveniu a hiperalgesia mecânica medida 3 horas depois da administraçao de carragenina (300 µg / paw) na pata posterior de ratos. A administração de ??meATP (50 µg /paw) induziu hiperalgesia mecânica 1 hora, mas não 3 horas, depois da sua administração, que foi prevenida pela dexametasona ou pelo A317491. Doses sublimiares de PGE2 (4 ng / paw) ou dopamina (0.4 µg / paw) que não induzem hiperalgesia por si só, induziram hiperalgesia, 3 horas depois, quando administradas logo depois de ??meATP ou carragenina em ratos tratados com dexametasona. Esses estados de hiperalgesia ("priming") revelados pelas doses sublimiares de PGE2 ou dopamine foram prevenidos pelo A317491 ou pelo tratamento com administração intraganglionar (DRG-L5) de ODN antisense, mas não pelo ODN mismatch, contra o receptor P2X3 (40 µg /5µL once a day for 4 days). ODN antisense, mas não o ODN mismatch, reduziu a expressão dos receptores P2X3 no nervo safeno e no DRG-L5. Para verificar se a PKC? media esse estado de hiperalgesia, inibidor de translocação de PKC? (1 µg/paw) foi administrado no tecido periférico 45 minutos antes do ??meATP ou PGE2 (100 ng/paw). O inibidor de PKC? preveniu o estado de hiperalgesia induzido pelo ??meATP ("priming"), mas não a hiperalgesia mecânica induzida pela PGE2 (100 ng/paw). Dessa maneira, os resultados desse estudo sugerem que a hiperalgesia inflamatória depended a ativação dos receptores P2X3 neuronais e da subsequente translocação da PKC? , que aumenta a susceptibilidade dos neurônios aferentes primários (priming) à ação de outros mediadores inflamatórios como a PGE2 e as aminas simpatomiméticas / Abstract: While inflammatory hyperalgesia depends on the release of prostaglandins and/or sympathetic amines that ultimately sensitize the primary afferent neurons, we have recently demonstrated that blockade of P2X3 receptor in the peripheral tissue completely prevents carrageenan-induced hyperalgesia. However, the mechanism by which the activation of neuronal P2X3 receptor contributes to the inflammatory hyperalgesia is not completely clear. The present study verifies whether the activation of P2X3 receptor on primary afferent neurons contributes to the mechanical hiperalgesia induced by prostaglandin E2 or dopamine in the peripheral tissue. Co-administration of A317491(60 µg / paw), a selective P2X3,2/3 receptor antagonist, or pre-treatment with dexamethasone (1 mg / mL / Kg), prevented the mechanical hyperalgesia measured 3 hours after the administration of carrageenan (300 µg / paw) in the rat's hind paw. The administration of ??meATP (50 µg /paw) induced mechanical hiperalgesia 1 hour, but not 3 hours, after its administration, which also was prevented by dexamethasone or A317491. Sub-threshold doses of PGE2 (4 ng / paw) or dopamine (0.4 µg / paw) that do not induce hyperalgesia by themselves, induced maximal hyperalgesia, 3 hours after, when administrated Just following ??meATP or carrageenan in rats treated with dexamethasone. These hyperalgesic states ("priming") revealed by sub-threshold doses of PGE2 or dopamine were prevented by A317491 or treatment with ganglionar administrations (DRG-L5) of ODN antisense, but not ODN mismatch, against P2X3 receptor (40 µg /5µL once a day for 4 days). ODN antisense, but not ODN mismatch reduced the expression of P2X3 receptors in the saphenous nerve and in DRG-L5. To verify whether PKC? mediates this hyperalgesic state, PKC? translocation inhibitor (1 µg/paw) was administrated in peripheral tissue 45 min. before ??meATP or PGE2 (100 ng/paw). PKC? inhibitor inhibited the hyperalgesic state induced by ??meATP ("priming"), but not the mechanical hyperalgesia induced by PGE2 (100 ng/paw). Briefly, the findings of this study suggest that the inflammatory hyperalgesia depends on neuronal activation of P2X3 receptor and the subsequent PKC? translocation, which increases the susceptibility of primary afferent neurons (priming) to others inflammatory mediators such as PGE2 and symphatetic amines / Mestrado / Fisiologia / Mestre em Biologia Funcional e Molecular

Receptor P2X3

Dor - Inflamação

Proteina quinase C-épsilon

P2X3 receptor

Inflammatory pain

Protein kinase C-epsilon

Mecanismos envolvidos na ação hiperalgésica induzida pela ativação de receptores P2X3 e P2X2/3 no músculo gastrocnêmio de ratos / Mechanisms underling the role of P2X3 and P2X2/3 receptors in mechanical hyperalgesia in gastrocnemius muscle of rats

Schiavuzzo, Jalile Garcia, 1980-

24 August 2018

Orientador: Maria Cláudia Gonçalves de Oliveira Fusaro / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Ciências Aplicadas / Made available in DSpace on 2018-08-24T04:40:35Z (GMT). No. of bitstreams: 1 Schiavuzzo_JalileGarcia_M.pdf: 1205741 bytes, checksum: b599c1bee7cda79ed3554fcb789eea9d (MD5) Previous issue date: 2013 / Resumo: Existem evidências do envolvimento do ATP via ativação do receptor P2X3 na dor muscular. Portanto, o objetivo deste estudo foi verificar se a ativação do receptor P2X3 no músculo gastrocnêmio de ratos induz hiperalgesia mecânica, e em caso afirmativo, analisar os mecanismos inflamatórios pelo qual os receptores P2x3 induzem hiperalgesia mecânica. O Antagonista não seletivo para o receptor P2X3 ?,?meATP foi administrado no músculo gastrocnêmio de ratos, induzindo hiperalgesia, a qual foi significativamente reduzida pelo antagonista seletivo do receptor P2X3 e P2X2/3 - A-317491. A hiperalgesia mecânica induzida pelo ?,?meATP foi reduzida pelo inibidor de ciclooxigenase Indometacina, pelo antagonista seletivo do receptor de Bradicinina B1 e B2- Dalbk e Bradyzide, respectivamente, antagonista dos adrenoceptores ?1 e ?2 - Atenolol e ICI 118,551 respectivamente, e inibidor não específico de selectinas Fucoidan. O ?,?meATP também induziu o aumento da concentração local de citocinas pro inflamatórias TNF-?, IL-1?, IL-6 e CIN e migração de neutrófilos. Juntos estes achados sugerem que o ?,?meATP induz hiperalgesia mecânica no músculo gastrocnêmio via ativação de receptor periférico P2X3, o qual envolve bradicinina, prostaglandinas e aminas simpatomiméticas e migração de neutrófilos. Portanto, nós sugerimos que os receptores P2X3 sejam um importante alvo no controle da dor muscular / Abstract: There is evidence of the involvement of endogenous ATP via activation of P2X3 in muscle pain. Therefore, the aim of this study was to verify whether the activation of P2X3 receptors in the gastrocnêmio muscle of rats induces mechanical hyperalgesia and, if so, to analyze the inflammatory mechanisms by which P2X3 receptors induce mechanical hyperalgesia. Intramuscular administration of the non-selective P2X3 receptor agonist ?,?-meATP in the gastrocnemius muscle of rats induced mechanical hyperalgesia, which was significantly reduced by the selective P2X3 and P2X2/3 receptors antagonist A-317491. The ?,?-meATP-induced mechanical hyperalgesia was prevented by the indomethacin cyclooxygenase inhibitor, the selective bradykinin B1- or B2- receptor antagonist DALBK and bradyzide, respectively, the ?1- or ?2-adrenoceptor antagonist atenolol and ICI 118,551, respectively, and the nonspecific selectin inhibitor fucoidan. ?,?-meATP also induced increase in the local concentration of the pro-inflammatory cytokines TNF-?, IL-1?, IL-6 and CINC-1 and the neutrophil migration. Together, these findings suggest that ?,?-meATP induced mechanical VIII hyperalgesia in the gastrocnemius muscle of rats via activation of peripheral P2X3 receptors, which involves bradykinin, prostaglandins, sympathetic amines, pro-inflammatory cytokines and neutrophil migration. Therefore, we suggest that P2X3 receptors are important targets to control muscle inflammatory pain / Mestrado / Biodinâmica do Movimento Humano e Esporte / Mestra em Ciências da Nutrição e do Esporte e Metabolismo

Hiperalgesia

Receptor P2X3

Músculos

Prostaglandinas

Hyperalgesia

P2X3 receptor

P2X2/3 receptor

Muscle

Prostaglandins

Wechselwirkungen von Agonisten und kompetitiven Antagonisten mit der Ligandenbindungsstelle des schnell desensitisierenden P2X3-Rezeptors

Helms, Nick

15 February 2016

Purinerge P2X3-Rezeptoren spielen eine bedeutende Rolle in der Vermittlung chronischer Schmerzen, welche ein führendes Problem des Gesundheitswesens mit vielen sozioökonomischen Konsequenzen darstellen. Die Tatsache, dass P2X3-Rezeptoren fast ausschließlich von nozizeptiven Neuronen exprimiert werden, macht sie trotz ihres besonderen Desensitisierungsverhaltens zu vielversprechenden Angriffspunkten zukünftiger Schmerztherapien, beispielsweise mithilfe kompetitiver Antagonisten an diesen Rezeptoren. Zur Analyse der Wechselwirkungen zwischen Agonist und kompetitivem Antagonist wird meist der Schild-Plot benutzt. Jedoch ist dieser im Falle der sehr schnell desensitisierenden P2X3-Rezeptoren ungeeignet, da die Vorbedingung eines stabilen Gleichgewichts zwischen Agonist und Antagonist aufgrund der Desensitisierung nicht erfüllt ist. Ziel der vorliegenden Arbeit war es, eine neue Methode zur Analyse der Interaktion kompetitiver Antagonisten mit ihrer Bindungsstelle am Beispiel des P2X3-Rezeptors zu entwickeln und so für die Antagonistenbindung bedeutende Aminosäuren der Bindungsstelle zu identifizieren. Mittels der Patch-Clamp-Technik wurden die Effekte der Antagonisten A-317491, TNP-ATP und PPADS auf die vom P2X1,3-Rezeptor-selektiven Agonisten α,β-MeATP induzierten Ströme am P2X3-Wildtyp-Rezeptor und an fünf Rezeptormutanten mit veränderter Ligandenbindungsstelle untersucht. Alle Rezeptoren wurden in HEK293-Zellen exprimiert. Anhand der gemessenen Daten wurde ein Hidden Markov Model (HMM) erstellt, welches die sequentiellen Übergänge des Rezeptors von geschlossen zu offen und desensitisiert in An- und Abwesenheit des Antagonisten miteinander kombiniert. Die am P2X3-Rezeptor induzierten Ströme konnten mithilfe dieses Modells korrekt gefittet und die für die Antagonistenbindung wichtigen Aminosäuren innerhalb der Bindungsstelle bestimmt werden. Als Resultat dieser Arbeit konnte außerdem gezeigt werden, dass das HMM eine geeignete Methode zur Analyse der Wirkung kompetitiver Antagonisten an schnell desensitisierenden Rezeptoren darstellt. Die untersuchten Antagonisten A-317491 und TNP-ATP haben einen kompetitiven Wirkmechanismus, während PPADS eine pseudoirreversible Blockade verursacht.

P2X3-Rezeptor

Markov Model

Antagonist

A-317491

TNP-ATP

PPADS

P2X3-Receptor

Markov Model

Antagonist

A-317491

TNP-ATP

PPADS

ddc:610

Wechselwirkungen von Agonisten und kompetitiven Antagonisten mit der Ligandenbindungsstelle des schnell desensitisierenden P2X3-Rezeptors

Helms, Nick

07 January 2016

Purinerge P2X3-Rezeptoren spielen eine bedeutende Rolle in der Vermittlung chronischer Schmerzen, welche ein führendes Problem des Gesundheitswesens mit vielen sozioökonomischen Konsequenzen darstellen. Die Tatsache, dass P2X3-Rezeptoren fast ausschließlich von nozizeptiven Neuronen exprimiert werden, macht sie trotz ihres besonderen Desensitisierungsverhaltens zu vielversprechenden Angriffspunkten zukünftiger Schmerztherapien, beispielsweise mithilfe kompetitiver Antagonisten an diesen Rezeptoren. Zur Analyse der Wechselwirkungen zwischen Agonist und kompetitivem Antagonist wird meist der Schild-Plot benutzt. Jedoch ist dieser im Falle der sehr schnell desensitisierenden P2X3-Rezeptoren ungeeignet, da die Vorbedingung eines stabilen Gleichgewichts zwischen Agonist und Antagonist aufgrund der Desensitisierung nicht erfüllt ist. Ziel der vorliegenden Arbeit war es, eine neue Methode zur Analyse der Interaktion kompetitiver Antagonisten mit ihrer Bindungsstelle am Beispiel des P2X3-Rezeptors zu entwickeln und so für die Antagonistenbindung bedeutende Aminosäuren der Bindungsstelle zu identifizieren. Mittels der Patch-Clamp-Technik wurden die Effekte der Antagonisten A-317491, TNP-ATP und PPADS auf die vom P2X1,3-Rezeptor-selektiven Agonisten α,β-MeATP induzierten Ströme am P2X3-Wildtyp-Rezeptor und an fünf Rezeptormutanten mit veränderter Ligandenbindungsstelle untersucht. Alle Rezeptoren wurden in HEK293-Zellen exprimiert. Anhand der gemessenen Daten wurde ein Hidden Markov Model (HMM) erstellt, welches die sequentiellen Übergänge des Rezeptors von geschlossen zu offen und desensitisiert in An- und Abwesenheit des Antagonisten miteinander kombiniert. Die am P2X3-Rezeptor induzierten Ströme konnten mithilfe dieses Modells korrekt gefittet und die für die Antagonistenbindung wichtigen Aminosäuren innerhalb der Bindungsstelle bestimmt werden. Als Resultat dieser Arbeit konnte außerdem gezeigt werden, dass das HMM eine geeignete Methode zur Analyse der Wirkung kompetitiver Antagonisten an schnell desensitisierenden Rezeptoren darstellt. Die untersuchten Antagonisten A-317491 und TNP-ATP haben einen kompetitiven Wirkmechanismus, während PPADS eine pseudoirreversible Blockade verursacht.

info:eu-repo/classification/ddc/610

ddc:610