Rôle du récepteur orphelin GPR88 dans les pathologies psychiatriques et motrices / Role of the orphan receptor GPR88 in psychiatric and motor disorders

Meirsman, Aura Callia Carole

25 September 2015

GPR88 est un récepteur couplé aux protéines G orphelin exprimé principalement au niveau du striatum spécifiquement dans les neurones moyens épineux de la voie striato-nigrale et de la voie striato-pallidale.Premièrement nous avons étudié les souris Gpr88 KO et montré des altérations biochimiques, structurales et comportementales. Aussi les résultats montrent que l’hyperactivité des souris Gpr88 KO est diminuée par l’administration de méthylphénidate. Deuxièmement nous avons montré que la diminution des comportements liés à l’anxiété dépend de GPR88 dans la voie striato-pallidale et que la coordination motrice est régulée par GPR88 dans le striatum adulte (injection AAV-Cre) et dans la voie striato-pallidale. Dernièrement, nous avons confirmé un déficit d’inhibition du prépulse chez les souris Gpr88 KO, mais aussi montré que celui-ci s’étend à la modalité visuelle et n’est pas lié à un déficit général d’inhibition ou à la délétion de Gpr88 dans les neurones striato-pallidaux. / Among brain orphan G protein-coupled receptors, GPR88 shows high expression mainly in the striatum specifically in medium spiny neurons of both the striatonigral and striatopallidal pathwaysFirst, we examine full Gpr88 KO mice and show biochemical, structural and behavioral alterations. Results also show that the hyperactivity phenotype of Gpr88 KO mice is reversed by methylphenidate.Second, we show that Gpr88 in striatopallidal neurons (cKO approach) exerts anxiogénic activity and that motor coordination is regulated by GPR88 in the adult brain (AAV-Cre approach) and in the striatopallidal pathway.Finally, we confirmed previous data showing impaired acoustic prepulse inhibition in Gpr88 KO mice and further show that this deficit is not the result of a general inhibition deficit or of the lack of GPR88 in striatopallidal neurons.

Récepteur couplé à protéine G

Anxiété

Coordination motrice

Inhibition du prépulse

Striatum

Neurones moyen épineux

G protein coupled receptor

Anxiety

Motor coordination

Prepulse inhibition

Striatum

Medium spiny neurons

572.8

616.8

Human δ opioid receptor Phe27 and Cys27 variants:the role of heteromerization and pharmacological chaperones in receptor processing and trafficking

Leskelä, T. (Tarja)

29 November 2011

Abstract The opioid receptors (δ, κ and μ) are family A G protein-coupled receptors (GPCRs) that have an important role in the regulation of pain. Like all GPCRs they have a common structure that consists of seven transmembrane domains with an extracellular amino (N)-terminus and an intracellular carboxyl-terminus. The human δ opioid receptor (h(δOR) has two polymorphic variants. A single-nucleotide polymorphism causes replacement of Phe with Cys at the amino acid position 27 in the receptor N-terminus. The allelic frequency of hδORCys27, the less common variant, is about 10% in Caucasians. In this study, the two hδOR variants were expressed in heterologous expression systems and their biosynthesis was characterized in detail using various cell biological and biochemical techniques. In particular, the role of receptor heteromerization and opioid receptor pharmacological chaperones in processing, maturation and trafficking of the variants was assessed. The hδOR variants showed significant differences in maturation and trafficking. The hδORCys27 had a significantly lower maturation efficiency compared with hδORPhe27. In addition, long-term receptor expression led to the accumulation of hδORCys27 in the endoplasmic reticulum (ER) and also impaired receptor targeting to ER-associated degradation. The hδOR variants also differed at the cell surface, as the hδORCys27 variant was internalized constitutively in a faster and more extensive manner than hδORPhe27. However, the variants had similar pharmacological properties and activated G proteins in an identical manner. This study also showed that hδORCys27 acted in a dominant negative manner and redirected some hδORPhe27 precursors to degradation. This resulted in impaired plasma membrane expression of hδORPhe27 in co-transfected cells. The hδOR variants were found to form heteromers early in the secretory pathway, which is the most likely reason for the dominant negative behavior of hδORCys27 on hδORPhe27. The mechanism of action of opioid receptor pharmacological chaperones, membrane-permeable opioid ligands, was investigated in detail using hδORCys27 and its mutant form hδORCys27-(Asp95Ala) as models. Opioid antagonists were found to be able to bind to and stabilize receptor precursors in the ER and enhance their dissociation from the ER molecular chaperone calnexin. This led to an increase in the number of receptors at the plasma membrane. In addition, hδORPhe27, like hδORCys27, was responsive to antagonist treatment whether the variants were expressed together or individually. / Tiivistelmä Opioidireseptorit kuuluvat G-proteiinikytkentäisiin reseptoreihin, ja niillä on tärkeä rooli kipuaistimuksen säätelyssä. Ne ovat solukalvoproteiineja, joiden aminohappoketju läpäisee kalvon seitsemän kertaa. Reseptorien aminoterminaalipää sijaitsee solun ulkopuolella ja karboksiterminaalipää solun sisällä. Ihmisen δ-opioidireseptori esiintyy kahtena polymorfisena muotona, Phe27:nä ja Cys27:nä, joissa aminohappo 27 on joko fenyylialaniini (Phe) tai kysteiini (Cys). Cys27 on harvinaisempi muoto, ja sen yleisyys on noin 10 % eurooppalaista alkuperää olevalla väestöllä. Tämän väitöskirjan tavoitteena oli tutkia δ-opioidireseptorin varianttimuotojen biosynteesiä reseptoriproteiinia tuottavissa heterologisissa solumalleissa (HEK293- ja SH-SY5Y-solut) solubiologisilla ja biokemiallisilla menetelmillä.. Väitöskirja osoittaa, että δ-opioidireseptorin varianttimuotojen välillä on eroa prosessoinnissa. Cys27-varianttia kuljetetaan endoplasmakalvostosta solun pinnalle vähemmän kuin Phe27-varianttia, ja pitkäaikainen reseptorituotanto johtaa vastasyntetisoituneiden reseptorien kerääntymiseen solun sisälle. Samalla reseptorien ohjaus proteasomihajotukseen heikkenee. Soluissa, jotka tuottavat molempia varianttimuotoja samanaikaisesti, Cys27-variantin havaittiin ohjaavan myös Phe27-varianttia proteasomihajotukseen vähentäen sen kuljetusta solun pinnalle. Tämä Cys27-variantin dominanttinegatiivinen ominaisuus johtuu todennäköisesti siitä, että variantit muodostavat dimeerisen rakenteen endoplasmakalvostossa. Havaittiin myös, että Cys27-varianttireseptorit ohjataan solun pinnalta lysosomihajotukseen tehokkaammin kuin vastaavat Phe27-varianttimuodot. Prosessointieroista huolimatta variantit eivät poikkea toisistaan farmakologisilta ominaisuuksiltaan, ja ne aktivoivat G proteiineja samalla tavalla. Väitöskirjassa tutkittiin myös farmakologisten kaperonien toimintamekanismeja käyttämällä mallina δ-opioidireseptorin Cys27-varianttia ja sen pistemutaatiota (Asp95Ala). Farmakologisten kaperonien eli reseptorispesifisten ligandien todettiin sitoutuvan reseptoreihin endoplasmakalvostossa ja stabiloivan niiden rakennetta, mikä vähentää reseptorin ja proteiinien laadunvalvontaan osallistuvan kaperonin, kalneksiinin, välistä vuorovaikutusta. Tämä johtaa reseptorien määrän kasvuun solun pinnalla.

ER-associated degradation

G protein-coupled receptor

endoplasmic reticulum

heteromerization

opioid receptor

pharmacological chaperone

polymorphism

trafficking

G-proteiinikytkentäinen reseptori

dimeeri

dominanttinegatiivisuus

farmakologinen kaperoni

opioidireseptori

polymorfia

Effects of chronic hypoxia on myocardial gene expression and function

Ronkainen, V.-P. (Veli-Pekka)

07 August 2012

Abstract Molecular oxygen is a prerequisite for essential metabolic processes in multicellular organisms. However, the supply of oxygen can be disturbed and tissue aerobic metabolism becomes compromised in several pathophysiological conditions. In prolonged hypoxia, cells initiate cell type-specific adaptation processes, which are typically mediated by alterations in gene expression. Changes are mainly driven by a transcription factor called hypoxia-inducible factor 1 (HIF-1). Heart muscle is a highly oxidative tissue and HIF-1 activation turns on myocardial adaptation mechanisms for enhanced survival in oxygen-deprived conditions. The aim of this study was to characterize myocardial gene expression changes during chronic hypoxia and couple the adaptational changes to cardiomyocyte function. The role of hypoxia and HIF-1 activation was studied by using in vitro mouse and rat heart cell culture models, tissue perfusions and in vivo infarction models. In this study, apelin, sarcoplasmic reticulum Ca2+-ATPase (SERCA2a) and G protein-coupled receptor 35 (GPR35) were characterized as novel functionally important myocardial HIF-1 target genes. Apelin and GPR35 were induced in hypoxia, while SERCA2a expression was reduced HIF-1 dependently. HIF-1 activation also altered cardiac myocyte contractility through modulation of SERCA2a and GPR35 expression, leading to impairment of the cellular calcium metabolism. Reduced contractility was suggested to serve as an adaptive mechanism for reduced aerobic ATP production in hypoxic conditions. This study presents novel information about the plasticity of myocardial adaptation to prolonged hypoxia. The role of a conserved transcription factor, HIF-1, was shown to be essential in the adaptation process in the myocardial cells. / Tiivistelmä Riittävä hapensaanti on välttämätöntä monisoluisten eliöiden elintoiminnoille. Hapensaanti voi kuitenkin häiriintyä erilaisissa tautitiloissa, jolloin happea käyttävät prosessit estyvät. Hapenpuutteen (hypoksia) pitkittyessä elimistön solut aloittavat sopeutumisen tilanteeseen muuttamalla toimintaansa geenien ilmentymismuutosten kautta. Adaptaatiota ohjaa pääasiassa hypoksia-indusoituva tekijä 1 (HIF-1). Sydän käyttää runsaasti happea energiantuotannossaan. Hapenpuutteen aikana HIF-1-transkriptiotekijä muuttaa sydämen geenien ilmentymistä siten, että sydänsolut selviävät paremmin happivajaissa olosuhteissa. Tämän tutkimuksen tavoitteena oli määrittää sydämen geenien ilmentymisen hapenpuutevasteita ja yhdistää muutokset sydänsolujen toiminnallisiin muutoksiin. Hapenpuutteen ja HIF-1:n merkitystä sopeutumisessa tutkittiin käyttäen malleina rotan ja hiiren sydänsoluviljelmiä, in vitro-kudosperfuusiomalleja sekä in vivo-sydäninfarktimalleja. Tässä työssä havaittiin apeliinin, sarkoplasmisen kalvoston Ca2+-ATPaasin (SERCA2a) sekä G-proteiinikytketyn reseptori 35:n olevan toiminnallisesti tärkeitä HIF-1:n säätelemiä geenejä sydämessä. Apeliinin sekä GPR35:n ilmentyminen lisääntyi hypoksian aikana, mutta SERCA2a:n ilmentyminen sen sijaan väheni HIF-1 –aktivaation seurauksena. HIF-1 –aktivaation osoitettiin myös vähentävän sydänsolujen supistustoimintaa muuttuneiden SERCA2a:n ja GPR35:n ilmentymisten kautta. Heikentynyt supistustoiminta sopeuttaa soluja vähentyneeseen aerobiseen ATP:n tuottoon hapenpuutteen aikana. Tämä tutkimus antaa lisätietoa sydämen sopeutumiskyvyn mukautumisesta pitkittyneeseen hapenpuutteeseen. Lisäksi tutkimus osoittaa HIF-1:n roolin olevan oleellinen myös sydänsolujen hypoksia-adaptaatioprosesseissa.

G protein-coupled receptors

adaptation

cardiac myocyte

heart

hypoxia

metabolism

oxygen homeostasis

G-proteiinikytketty reseptori

aineenvaihdunta

hapenpuute

happitasapaino

sopeutuminen

sydän

sydänlihassolu

Modulation endogène des récepteurs métabotropiques du glutamate : bases moléculaires et implications fonctionnelles de la sensibilité au chlore extracellulaire / Endogenous modulation of metabotropic glutamate receptors : molecular basis and functional implications of extracellular chloride sensitivity

Tora, Amélie

20 October 2015

Les récepteurs métabotropiques du glutamate (mGluRs) sont des récepteurs couplés aux protéines G (RCPGs) modulant la transmission synaptique au sein du système nerveux central. D'un point de vue structural, ils ont la particularité de posséder un large domaine extracellulaire, le Venus Flytrap (VFT), où se lie leur ligand endogène, le glutamate. Leur domaine transmembranaire à 7 hélices, commun à tous les RCPGs, est connu pour être la cible d'une nouvelle classe de molécules à visée thérapeutique, les modulateurs allostériques. Au contraire, le VFT est le siège du développement de ligands compétitifs du glutamate et peu de choses sont connues quant à l'existence de modulateurs allostériques du VFT. Des études récentes ont mis en évidence une sensibilité des mGluRs aux ions extracellulaires et en particulier au chlore (Cl-), sans que son site de liaison ne soit identifié. Dans ce contexte, ce travail de thèse explore la possibilité d'une modulation allostérique endogène des mGluRs par les ions Cl-, en identifiant leur(s) site(s) de liaison(s) et leur effet sur la dynamique conformationnelle et la fonction des récepteurs. En combinant une approche pharmacologique, biophysique basée sur la technique de FRET, et la modélisation, nous avons tout d'abord confirmé que le Cl- potentialise l'action du glutamate sur tous les mGluRs et qu'il favorise la conformation active des récepteurs en se liant au niveau du VFT. Les mGluRs présentent également une sensibilité différente au Cl-, mGlu4 étant le plus sensible et mGlu2 le moins. Ceci s'explique notamment par le nombre de sites fonctionnels, tous les mGluRs dont mGlu4 possédant 2 sites par monomère à l'exception de mGlu2 qui n'en possède qu'un, en raison d'une mutation « clé » d'une sérine en aspartate dans le lobe 1 du VFT. D'autre part, le récepteur mGlu3 est apparu comme un cas particulier ayant une sensibilité accrue au Cl-, son domaine VFT cumulant la présence et l'orientation adéquate d'acides aminés formant un « verrou » Cl-, qui favorise de manière drastique la conformation active et une activité basale élevée de ce récepteur. Enfin, la modélisation de la variation de la concentration extracellulaire en Cl- lors d'une activité synaptique GABAergique est compatible avec une modulation des mGluRs les plus sensibles. En conclusion, le Cl- est un modulateur allostérique endogène des mGluRs et l'exploitation de ses sites de liaison au sein du VFT pourrait permettre le développement de nouveaux agents thérapeutiques. / Metabotropic glutamate receptors (mGluRs) are G coupled-protein receptors (GPCRs) playing key roles in synaptic transmission in the central nervous system. They display a large extracellular domain, the Venus Flytrap (VFT) where the endogenous ligand, glutamate, binds. Their 7 transmembrane helices spanning domain, common to all GPCRs, is known to be the target of new therapeutic compounds, called allosteric modulators. In contrast, VFT domain is used to develop glutamate competitive ligands and there are only few data about allosteric modulators targeting the VFT. Recent studies have shown mGluRs are sensitive to extracellular ions, particularly to chloride (Cl-), although its binding site has not been elucidated. This thesis work explores the possibility of an endogenous allosteric modulation of mGluRs by Cl-, aiming to delineate its binding site(s) and its effect on receptor conformational dynamics and function. Using pharmacological, FRET based biophysical approaches and modelling, we have first confirmed that Cl- potentiates glutamate action in all mGluRs and that this ion favors agonist induced active conformation by binding to the VFT. mGluRs are also differently sensitive to Cl-, mGlu4 being the most and mGlu2 the least. This difference is notably explained by the number of Cl- functional sites within the VFT, all mGluRs including mGlu4 displaying 2 sites per monomer whereas mGlu2 has only 1 site due to a serine-aspartate “key” mutation in VFT lobe 1. Besides, mGlu3 receptor appears to be a “special case”, as this receptor is highly sensitive to Cl- because its VFT domain is carrying amino acids creating a “Cl- lock”, which dramatically favors active conformation and a high level of basal activity. Finally, modelling of extracellular Cl- concentration variations in a GABAergic synapse is compatible with a modulation of the most sensitive mGluRs. In conclusion, Cl- is an endogenous allosteric modulator of mGluRs and exploiting its binding sites may yield to the development of innovative therapeutic tools.

Récepteurs couplés aux protéines G

Glutamate

Modulateur allostérique

Chlore

Synapse GABAergique

G protein-Coupled receptors

Glutamate

Allosteric modulator

Chloride

GABAergic synapse

Engineering the angiotensin II type 1 receptor for structural studies

Thomas, Jennifer Ann

January 2015

G protein-coupled receptors (GPCRs) are eukaryotic integral membrane proteins that perform transmembrane signal transduction. Due to their pivotal role in a wide range of essential physiological functions GPCRs represent a high proportion of all drug targets. High resolution X-ray structures of GPCRs are however underrepresented in the Protein Data Bank. This is due to their instability in detergent, low expression levels and the presence of misfolded receptors in many heterologous expression systems. The objective of this project was to engineer the angiotensin II type 1 receptor (AT1R), a human GPCR, to make it suitable for structural studies. It was determined that detergentsolubilised AT1R was thermostable with antagonist bound with an apparent Tm of ~45°C, which was sufficiently stable for purification without further thermostabilisation by rational mutagenesis. Two expression systems were then evaluated for large-scale production of AT1R, namely baculovirus-mediated expression in insect cells and mammalian expression in HEK293 cells. Radioligand binding assays showed that only the mammalian system produced sufficient quantities of active AT1R for structural studies. Expression in the mammalian system was further optimised to approximately 6 mg/L. An AT1R-GFP fusion was created to examine membrane localisation using confocal laser scanning microscopy, to assay expression levels, to select highly expressing monoclonal cell lines using fluorescence activated flow cytometry and to develop a fluorescence size-exclusion chromatographybased assay to examine the suitability of 12 different ligands for co-crystallization. AT1R was also engineered to facilitate crystallisation, including C-terminal truncations to remove predicted disordered regions and bacteriophage T4-lysozyme being added to the third intracellular loop to provide additional points of contact for crystallisation, which increased the apparent Tm by approximately 10°C. All modified versions of AT1R were assessed for expression, stability and monodispersity. Additionally a rapid western blotting based assay was developed for the detection of unfolded membrane proteins, which will have wide applicability in the field.

572

Activation Of Glycoprotein Hormone Receptors : Role Of Different Receptor Domains In Hormone Binding And Signaling

Majumdar, Ritankar

04 1900

The glycoprotein hormones, Luteinizing Hormone (LH), human Chorionic Gonadotropin (hCG), Follicle Stimulating Hormone (FSH) and Thyroid Stimulating Hormone (TSH) are heterodimeric proteins with an identical α-subunit associated non-covalently with the hormone specific β-subunit and play important roles in reproduction and overall physiology of the organism [1]. The receptors of these hormones belong to the family of G-protein coupled receptors (GPCR) and have a large extracellular domain (ECD) comprising of 9-10 leucine rich repeats (LRR) followed by a flexible hinge region, a seven helical transmembrane domain (TMD) and a C terminal cytoplasmic tail [2]. Despite significant sequence and structural homologies observed between the ECDs of the receptors and the specific β-subunits of the hormones, the hormone-receptor pairs exhibit exquisite specificity with very low cross-reactivity with other members of the family. The TSH receptor (TSHR) is an especially interesting member of this family as it not only recognizes is cognate ligand, i.e. TSH, but also binds to the non-cognate ligands such as autoantibodies. TSHR autoantibodies come in different flavors; inhibitory antibodies that compete with the hormone for receptor binding and block its action, stimulatory antibodies that activate the receptor in a hormone independent manner and neutral antibodies that bind to the receptor but do not directly influence its functions. The inhibitory autoantibodies cause hypothyroidism and are responsible for Hashimoto’s Thyroiditis, whereas the stimulatory autoantibodies cause Graves’ thyrotoxicosis characterized by hyperthyroid condition [3]. The exact epitopes of these autoantibodies are not well delineated although it has been hypothesized that the blocking type- and the stimulatory type- autoantibodies have predominant epitopes in the TSHR ECD that overlap with hormone binding regions [4]. Insights into the mode of hormone or autoantibody binding to the receptor was primarily derived from the crystal structure of FSHR leucine rich repeat domain (LRRD) bound to single chain analog of FSH, and the crystal structures of TSHR LRRD bound to the stimulatory type human monoclonal antibody M22 [5] and the inhibitory type- monoclonal antibody K1-70 [6]. Both these crystal structures propose LRRDs as the primary ligand binding site which interacts with the hormone through its determinant loop in a hand-clasp fashion [7] while the autoantibodies mimics the hormone binding to a large extent [8] . These structures, while providing detailed understanding of the molecular interactions of the LRRs with the hormone, shed little light on the mechanism by which the signal generated at the LRRD are transduced to the downstream effector regions at the distally situated TMD. Hence, while one understands the ligand binding to a large extent, the activation process is not well understood, one of the central objective of the present study. Ligand-receptor interactions are typically studied by perturbing ligand/receptor structure by mutagenesis or by mapping conformational changes by biophysical or computational approaches. In addition to the above-mentioned approaches, the present work also uses highly specific antibodies against different domains of the receptor as molecular probes due to the ability of antibodies to distinguish between conformations likely to arise during the activation process. Use of antibodies to understand the receptor activation process is especially apt for TSHR due to the presence of physiologically relevant TSHR autoantibodies and their ability to influence hormone binding and receptor activation [9, 10]. Chapter 2 attempts to provide a comparison between the interactions of the hormone and the autoantibodies with TSHR. For this purpose, two assays were developed for identification of TSHR autoantibodies in the sera of patients suffering from autoimmune thyroid diseases (AITD), the first assay is based on the ability of TSHR autoantibodies to compete for radiolabeled hormone (The TSH binding inhibition (TBI), assay) and the second based on the capability of stimulatory antibody to produce cAMP in cells expressing TSHR (TSHR stimulatory immunoglobin (TSI) assay). A stable cell line expressing TSHR capable of recognizing both TSH and TSHR autoantibodies was thus created and used for prospective and retrospective analysis of AITD patients. Based on the TBI and TSI profiles of IgGs, purified from AITD patient's sera, it was recognized that TSHR stimulatory and TSH binding inhibitory effects of these antibodies correlated well, indicating overlap between hormone binding and IgG binding epitopes. It was also recognized that stimulatory IgGs are not affected by negative regulatory mechanism that governs TSH secretion substantiating the persistence of these antibodies in circulation. Kinetics of cAMP production by Graves’ stimulatory IgG was found to be fundamentally distinct, where the autoantibodies displayed pronounce hysteresis during the onset of the activation process when compared to the hormone. This could possibly be explained by the oligoclonality of the autoantibody population, a different mechanism of receptor activation or dissimilarity in autoantibody and hormone epitopes. To gain additional insights into the epitopes of TSHR autoantibodies and the regions that might be critical in the activation process, different overlapping fragments encompassing the entire TSH receptor ECD were cloned, expressed in E.coli as GST fusion proteins and purified: 1] the first three LRRs (TLRR 1-3, amino acid (aa) 21-127), 2] the first six LRRs (TLRR 1-6, aa 21-200), 3] the putative major hormone binding domain (TLRR 4-6, aa 128-200), and 4] the hinge region of TSH receptor along with LRR 7 to 9, (TLRR 7-HinR, aa 201-413). The receptor fragment TLRR 7-HinR was further subdivided into LRR 7-9 (TLRR 7-9, aa 201-161) and the hinge region (TSHR HinR, aa 261-413), expressed as N-terminal His-Tagged protein and purified using IMAC chromatography. Simultaneously, the full-length TSHR ECD was cloned, expressed and purified using the Pichia pastoris expression system. ELISA or immunoblot analysis of autoantibodies with the TSHR exodomain fragments suggested that Graves’ stimulatory antibody epitopes were distributed throughout the ECD with LRR 4-9 being the predominant site of binding. Interestingly, experiments involving neutralization of Graves’ IgG stimulated cAMP response by different receptor fragment indicated that fragments corresponding to the TSHR hinge region were better inhibitors of autoantibody stimulated receptor response than corresponding LRR fragments, suggesting that the hinge region might be an important component of the receptor activation process. This was in contrast to prevalent beliefs that considered the hinge region to be an inert linker connecting the LRRs to the TMD, a structural entity without any known functional significance. Mutagenesis in TSHR hinge region and agonistic antibodies against FSHR and LHR hinge regions, reported by the laboratory, recognized the importance of the hinge regions as critical for receptor activation and may not simply be a scaffold [11-13]. Unfortunately, the mechanism by which the hinge region regulates binding or response or both have not been well understood partially due to unavailability of structural information about this region. In addition poor sequence similarity within the GpHR family and within proteins of known structure, make this region difficult to model structurally. In chapter 3, effort is made to model the hinge regions of the three GpHR based on the knowledge driven and Ab initio protocols. An assembled structure comprising of the LRR domain (derived from the known structures of FSHR and TSHR LRR domains) and the modeled hinge region and transmembrane domain presents interesting differences between the three receptors, especially in the manner the hormone bound LRRD is oriented towards the TMD. These models also suggested that the α-subunit interactions in these three receptors are fundamentally different and this was verified by investigating the effects of two α-subunit specific MAbs C10/2A6 on hCG-LHR and hTSH-TSHR interactions. These two α-subunit MAbs had inverse effects on binding of hormone to the receptor. MAb C10 inhibited TSH binding to TSHR but not that of hCG, whereas MAb 2A6 inhibited binding of hCG to LHR but not of hTSH. Investigation into the accessibility of their epitopes in a preformed hormone receptor complex indicated that the α-subunit may become buried or undergo conformational change during the activation process and interaction may be different for LHR and TSHR. Fundamental differences in TSHR and LHR were further investigated in the next chapter (Chapter 4), especially with regards to the ligand independent receptor activation. Polyclonal antibodies were developed against LRR 1-6, TLRR 7-HinR and the TSHR HinR receptor fragments. The LRR 1-6 antibodies were potent inhibitor of receptor binding as well as response, similar to that observed with antibodies against the corresponding regions of LHR. Interestingly, the antibodies against the hinge region of TSHR were unable to inhibit hTSH binding, but were effective inhibitors of cAMP production suggesting that this region may be involved in a later stage of a multi-step activation process. This was also verified by studying the mechanism of inhibition of receptor response and their effect on ligand-receptor association and dissociation kinetics. Hinge region-specific antibodies immunopurified from TLRR 7-HinR antibodies behaved akin to those of the pure hinge region antibodies providing independent validation of the above results. This result was, however, in contrast to those observed with a similar antibody against LHR hinge region. As compared to the TSHR antibody, the LHR antibody inhibited both hormone binding and response. In addition, this antibody could dissociate a preformed hormone-receptor complex which was not observed for TSHR hinge region antibodies. Although unable to dissociate preformed hormone-receptor complex by itself, the TSHR HinR antibodies augmented hormone induced dissociation of the hormone-receptor complex suggesting that this region may be involved in modulation of negative cooperativity associated with TSHR. Molecular dissection of the role of hinge region of TSHR was further carried out by using monoclonal antibodies against LRR 1-3 (MAb 413.1.F7), LRR 7-9 (MAb 311.87), TSHR hinge region (MAb 311.62 and MAb PD1.37). MAb 311.62 which identifies the LRR/Cb-2 junction (aa 265-275), increased the affinity of TSHR for the hormone while concomitantly decreasing its efficacy, whereas MAb 311.87 recognizing LRR 7-9 (aa 201-259) acted as a non-competitive inhibitor of TSH binding. MAb 413.1.F7 did not affect hormone binding or response and was used as the control antibody for different experiments. Binding of MAbs was sensitive to the conformational changes caused by the activating and inactivating mutations and exhibited differential effects on hormone binding and response of these mutants. By studying the effects of these MAbs on truncation and chimeric mutants of thyroid stimulating hormone receptor (TSHR), this study confirms the tethered inverse agonistic role played by the hinge region and maps the interactions between TSHR hinge region [14] and exoloops responsible for maintenance of the receptor in its basal state. Mechanistic studies on the antibody-receptor interactions suggest that MAb 311.87 is an allosteric insurmountable antagonist and inhibits initiation of the hormone induced conformational changes in the hinge region, whereas MAb 311.62 acts as a partial agonist that recognizes a conformational epitope critical for coupling of hormone binding to receptor activation. Estimation of apparent affinities of the antibody to the receptor and the cooperativity factor suggests that epitope of MAb 311.87 (LRR 7-9) may act as a pivot involved in the initial events immediate to hormone binding at the LRRs. The anatgonsitic effect of MAB 311.62 on binding and response also suggested that binding of hormone is conformationally selective rather than an induced event. The hinge region, probably in close proximity with the α-subunit in the hormone-receptor complex, acts as a tunable switch between hormone binding and receptor activation. In contrast to the stimulatory nature of Cb-2 antibody such as MAb 311.62, MAb PD1.37, which identified residues aa 366–384 near Cb-3, was found to be inverse agonistic. Unlike other known inverse agonistic MAbs such as CS-17 [15] and 5C9 [16], MAb PD1.37 did not compete for TSH binding to TSHR, although it could inhibit hormone stimulated response. Moreover, unlike CS-17, MAb PD1.37 was able to decrease elevated basal cAMP of hinge region constitutively activated mutations only but not those in the extracellular loops. This is particularly important as interaction of hinge region residues with those of ECLs had been thought to be critical in maintenance of the basal level of receptor activation and are responsible for attenuating the constitutive basal activity of the mutant and wild-type receptors in the absence of the hormone. This was demonstrated by a marked increase in the basal constitutive activity of the receptor upon the complete removal of its extracellular domain, which returned to the wild-type levels upon reintroduction of the hinge region. However, careful comparison of the activities of the mutants (receptors harboring deletions and gain-of-function mutations) with maximally stimulated wild-type TSHR indicated that these mutations of the receptor resulted primarily in partial activation of the serpentine domain suggesting that only the ECD in complex with the hormone is the full agonist of the receptor. Confirmation of the above proposition has been difficult to verify primarily due to a highly transient conformational change in the tripartite interaction of the hinge region/hormone and the ECLs. The current approaches of using antibodies to probe the ECLs are difficult due to the conformational nature of the antigen as well as difficulty in obtaining a soluble protein. In chapter 5, the ligand induced conformational alterations in the hinge regions and inter-helical loops of LHR/FSHR/TSHR were mapped using the exoloop specific antibodies generated against a mini-Transmembrane domain (mini-TMD) protein. This mini-TMD protein, designed to mimic the native exoloop conformations, was created by joining the TSHR exoloops, constrained through the helical tethers and library derived linkers. The antibody against mini-TMD specifically recognized all three GpHRs and inhibited the basal and hormone stimulated cAMP production without affecting hormone binding. Interestingly, binding of the antibody to all three receptors was abolished by prior incubation of the receptors with the respective hormones suggesting that the exoloops are buried in the hormone-receptor complexes. The antibody also suppressed the high basal activities of gain-of-function mutations in the hinge regions, exoloops and TMDs such as those involved precocious puberty and thyroid toxic adenomas. Using the antibody and point/deletion/chimeric receptor mutants, dynamic changes in hinge region-exoloop interactions were mapped. The computational analysis suggests that mini-TMD antibodies act by conformationally locking the transmembrane helices by restraining the exoloops and juxta-membrane regions. This computational approach of generating synthetic TMDs bears promise in development of interesting antibodies with therapeutic potential, as well as, explains the role of exoloops during receptor activation. In conclusion (Chapter 6), the study provides a comprehensive outlook on the highly dynamic interaction of ligand and different subdomains of the TSHR (and to a certain extent of LHR and FSHR) and proposes a model of receptor activation where the receptor is in a dynamic equilibrium between the low affinities constrained state and the high affinity unconstrained state and bind to the hormone through the LRR 4-6. Upon binding the βL2 loop of the hormone contact LRR 8-10 that triggers a conformational change in the hinge region driving the α-subunit to contact the ECLs. Upon contact, the ECLs cooperatively causes helix movement in the TMH and ultimately in ICLs causing the inbuilt GTP-exchange function of a GPCR.

Glycoprotein Hormone Receptors

Ligand Binding

Signal Transduction

Hormone Receptor Interactions

TSH Receptors

Thyrotropin Receptor

G-protein Coupled Receptors (GPCR)

Biochemistry

Characterisation of critical interactions between translation factors eIF2 and eIF2B

Murphy, Patrick

January 2013

Eukaryotic translation initiation is a complex and highly regulated process involving the ribosome, mRNA and proteins called eukaryotic initiation factors (eIFs). The overall aim of translation initiation is to position the ribosome at the initiation codon of the mRNA. eIF2, in its GTP-bound conformation, binds the initiator tRNA (Met-tRNAiMet) and delivers it to the 40S ribosomal subunit. When the anticodon of the tRNA is bound to the initiation codon, the GTP on eIF2 is hydrolysed to GDP. The guanine nucleotide exchange factor (GEF) eIF2B regenerates eIF2-GTP. eIF2 and eIF2B are multisubunit/multidomain protein complexes. Because information regarding the interface between each complex is limited, particularly the interface on the eIF2γ subunit, which binds the guanine-nucleotides and Met-tRNAiMet, interactions between the minimal GEF domain of eIF2Bε, εGEF, and eIF2 were mapped using mutagenesis and an in vitro cysteine cross-linking approach, with the cross-linker Mts-Atf-Biotin. Site-directed mutagenesis (SDM) was used to mutate five N-terminal and five C-terminal surface-exposed εGEF residues to cysteines. The mutant alleles were analysed in Saccharomyces cerevisiae and it was found that the gcd6-R574C allele was lethal and the gcd6-T572C was Gcd-. Further gcd6-R574 mutant alleles were also found to be lethal in yeast but expressed in vivo.εGEF-R574C has dramatically reduced GEF activity in vitro and binding assays showed that this mutant has significantly reduced affinity for eIF2. The εGEF-T572C and εGEF-S576C mutants also have severe and minor eIF2-binding defects respectively, while the C-terminal εGEF-Cys mutants have slightly reduced affinity for eIF2. The N-terminal εGEF-Cys mutants cross-link specifically to eIF2γ, while the C-terminal εGEF-Cys mutants interact predominantly with eIF2β. From the data obtained in this study, we propose a new model for eIF2B-mediated guanine-nucleotide exchange that reduces the importance of eIF2β and suggests εGEF resembles other GEFs in binding primarily to its G protein partner eIF2γ.

572.8

The role of human cytomegalovirus encoded viral G protein-coupled receptors in onco-modulatory signalling

Subramoney, Preya

22 June 2011

Human cytomegalovirus (HCMV) is a ubiquitous virus of the herpes type that infects a high percentage of some populations. One of the most researched genes expressed by HCMV with close homology to human chemokine receptors is the US28 G protein-coupled receptor. Study design: This study was initiated to elucidate the intracellular signalling pathways of an inflammatory factor (IL-6) and an angiogenic factor (STAT3) triggered by the viral US28 oncogene and the presence of US28 in the HCMV viral particle. These pathways were observed by introducing the US28 gene into two human cell lines by infection with a HCMV strain that expresses the US28 gene (wild type), and two HCMV strains where the US28 gene was deleted (ÄUS28 and ÄUS28/UL33). Special attention was directed at the expression of IL-6 after promotion of the US28 gene and subsequent phosphorolation of STAT3. A new US28 antibody was validated and a method developed in an attempt to determine US28 on the viral particle. The following techniques were applied: Cell culture work, two mammalian cell lines were used, HFF’s and U373 MG. Virus stock titre determination to determine the multiplicity of infection. Protein quantitation to determine very small quantities of protein for Western blot analysis. ELISA for the quantitative determination of IL-6. Western blotting for phospho- STAT3 determination and validation of the US28 antibody. Immunocytochemistry was used for back titrations of virally infected cells. Immunofluorescence assay and use of confocal microscopic techniques was used for the location of the US28 gene in the virion and for tSTAT3 translocation to the nucleus. Conclusion: A clear increase in IL-6 secretion (495% ± 1%) was seen, and this was after only an hour in HCMV WT infected cells. From the increase in IL-6 secretion a subsequent increase in STAT3 phosphorylation was detected in the same samples. A clear link has been established between IL-6 and STAT3. A method to determine whether US28 was present in the HCMV viral particle was designed and preliminary results obtained. The results were inclusive. / Dissertation (MSc)--University of Pretoria, 2011. / Pharmacology / unrestricted

Us28

Antibody

Tumour

Cytokine

Interleukin 6 il-6

Signal transducer

Activator of transcription stat3

Oncogene

Ligand

G protein-coupled receptors gpcr

Human cytomegalovirus hcmv

UCTD

Régulation de l'activité autophagique par les récepteurs chimiotactiques couplés aux protéines G : rôle essentiel dans la migration directionnelle / Inhibition of autophagic activity by chemotactic receptors coupled to G proteins : essential role in cell migration

Coly, Pierre-Michaël

02 February 2017

L’autophagie est un processus catabolique par lequel certaines protéines cytosoliquessont dirigées vers le compartiment lysosomial, afin d’y être dégradées. Ce processus débutepar la séquestration de constituants cytoplasmiques par une structure multimembranaireappelée phagophore. La fermeture du phagophore donne naissance à une vésicule à doublemembrane nommée autophagosome, qui fusionne avec les lysosomes, ce qui conduit à ladégradation du contenu de sa lumière. Ainsi, la modulation de l’autophagie permet unremodelage dynamique du protéome cellulaire. Bien que des données récentes ont permis dedémontrer la dégradation autophagique de protéines impliquées dans la migration cellulaire,telles que des intégrines, ou encore les protéines RhoA et Src, l'impact fonctionnel del'autophagie sur la migration cellulaire demeure sujet à controverse. Alors que l'autophagie estdécrite comme un processus pro-migratoire et pro-invasif dans certaines études, d'autrestravaux indiquent que l'inactivation des protéines pro-autophagiques stimule l'invasion descellules cancéreuses. De plus, l'effet fonctionnel des RCPG chimiotactiques sur l’activitéautophagique reste totalement inexploré. Sur la base de ces données, les objectifs de mon travail de thèse ont été i) d’évaluer les effets des RCPG chimiotactiques, le CXCR4 et l’UT,sur le processus autophagique et ii) d’étudier l’impact de cette modulation sur la migrationcellulaire. Pour ce faire, nous avons utilisé des cellules HEK-293, transfectées à l’aide deconstruits permettant l’expression des RCPG CXCR4 et UT, ainsi que la lignée deglioblastome humain U87, exprimant ces deux récepteurs de manière endogène.Nous avons dans un premier temps évalué l’activité autophagique à l’aide de laprotéine de fusion EGFP-LC3, marqueur des autophagosomes. Nous avons ainsi démontréque l’activation du CXCR4 et de l’UT provoque une diminution significative de la biogénèsedes autophagosomes. Une étape essentielle de cette biogenèse est le recrutement des protéinesAtg16L1 et Atg5 à la membrane plasmique, conduisant à la formation d'endosomes Atg16L1-Atg5-positifs, appelés « endosomes pré-autophagiques ». Cette population d’endosomesconstitue une source importante de phospholipides nécessaire à l’expansion du phagophore etla formation d’un autophagosome mature. Afin d’évaluer l’impact des RCPG chimiotactiquessur le recrutement de la protéine Atg16L1 à la membrane plasmique, nous avons bloqué leprocessus d’endocytose par l’utilisation d’un inhibiteur de la dynamine, le Dynasore. Cettemolécule provoque une accumulation marquée de la protéine Atg16L1 dans les endosomespré-autophagiques en formation, retenus à la membrane plasmique. / Autophagy is a catabolic process by which certain cytosolic proteins are directed to thelysosomal compartment to be degraded. This process begins with the sequestration ofcytoplasmic components, by a multimembrane structure called the phagophore. The closure ofthe phagophore gives rise to a double membrane vesicle called autophagosome, which thenmerges with lysosomes in order to degrade its luminal content. Autophagy modulation allowsa dynamic remodeling of the cellular proteome. Although recent evidence has demonstratedautophagic degradation of key proteins involved in cell migration, such as integrins, RhoAand the Src kinase, the functional impact of autophagy on cell migration remainscontroversial. While autophagy is described as a pro-migratory and pro-invasive process insome studies, others indicate that the inactivation of pro-autophagic proteins stimulates thecancer cell invasion. In addition, the functional effect of chemotactic GPCR on autophagicactivity remains unexplored. On the basis of these data, the objectives of my thesis were i) toevaluate the effects of the chemotactic GPCRs for SDF-1 (CXCR4) and for the vasoactivepeptide urotensin II (UT), on the autophagic process and ii) to study the impact of thismodulation on cell migration. In order to do this, we used HEK-293 cells, transfected with constructs allowing the expression of CXCR4 and UT, as well as the human glioblastomaline, U87, which endogenously expresses these two receptors. Previous studies have demonstrated a direct interaction of Atg5 with membranes,suggesting that recruitment of Atg16L1 to the plasma membrane may depend on Atg5. This prompted us to evaluate the formation of Atg16L1-positive pre-autophagic endosomes,following depletion of Atg5 levels. Several interfering RNAs, targeting the transcriptencoding Atg5, have been tested and, as expected, these interfering RNAs completely blockedthe recruitment of Atg16L1 to forming pre-autophagic endosomes. We then tested the effectsof chemotactic GPCRs on the subcellular localization of the Atg5 protein. By confocalmicroscopy, we found that a significant fraction of Atg5 localized to the plasma membraneunder basal conditions. The activation of CXCR4 or UT is accompanied by a marked decreaseof the Atg5 pool localized at the plasma membrane. Furthermore, we have demonstrated thatthe anti-autophagic effects of chemotactic GPCRs are completely abrogated byoverexpression of a recombinant Atg5 protein, suggesting that chemotactic GPCRs exert theiranti-autophagic effects by reducing the membrane pool of Atg5, necessary for the productionof pre-autophagic endosomes, and the expansion of the phagophore.

Dir.biologie medecine sante

Autophagie

Tumeur du cerveau

Récepteurs métabotropiques

Récepteurs couplés aux protéines G

Autophagy

Brain tumour

Metabotropic receptors

G protein-coupled receptors

Studium membránových receptorů pomocí vazby radioligandů / The study of membrane receptors by radioligands binding

Rejhová, Alexandra

January 2011

Drug addiction, opiates respectively, is a social problem which seriousness is currently on the rise. One of key elements causing addiction is tolerance to increasing doses of drug causing abstinence syndrome during withdrawal and craving. Opioid receptors are members of a large group of receptors coupled with heterotrimeric G-proteins (GPCR), whose properties can be investigated using agonist- stimulated binding [35 S] GTPγS. Many extracellular signals are transferred into a cell through GPCR. Opioid receptor agonists inhibit the activity of adenylyl cyclase and are coupled with G-protein group Gi/Go. This work is devoted to the study of changes in isolated plasma membranes of rat forebrain containing opioid receptors of healthy subjects with membranes acquired from morphine addicted subjects. The rats were long-term morphine treated in increasing doses, to develop the dependency. The comparison is done firstly by binding of [3 H]ouabain to Na,K-ATPase, which proves to be a negative standard of changes, secondly by binding [35 S]GTPγS to G-proteins, thereby providing the functional activity of G-protein in stimulating the binding by the agonist of δ-opioid receptors DADLE or agonist of µ-opioid receptors DAMGO. Furthermore, it has been studied the influence of prostaglandin E1 on binding [35...