Differential regulation of serotonin 2A receptor responsiveness by agonist-directed interactions with beta-arrestin2

Schmid, Cullen L.

31 March 2011

No description available.

Neurosciences

Pharmacology

G protein-coupled receptor

Serotonin 2A receptor

beta-arrestin2

hallucinogens

functional selectivity

Modulation orthostérique et allostérique du PAFR par des molécules synthétiques

Noël, Cynthia Jenny

January 2008

Le PAF (facteur d'activation des plaquettes) est un médiateur lipidique de l'inflammation très puissant impliqué dans plusieurs conditions pathophysiologiques.Le PAF agit principalement via un seul récepteur, le PAFR qui appartient à la famille des récepteurs couplés aux protéines G, les GPCRs. Le"two state model" assume que les GPCRs existent dans un état d'équilibre entre un état inactif (R) et un état actif (R*). L'isomérisation de R vers R* peut arriver de façon spontanée, c'est à dire indépendamment de la liaison d'un agoniste. Dans ces travaux de recherche, nous avons tenté de déterminer la propriété antagoniste et agoniste inverse des molécules orthostériques (WEB2086, PCA4248, FR49175, bromure d'octylonium, CV3988 et le Trans BTP dioxolane) à activer la voie des MAPK ainsi que le cycle biochimique des inositols phosphates dans la lignée cellulaire HEK 293 transfectée de façon stable avec le récepteur du PAF. De plus, l'activité potentiellement allostérique sur le PAFR de modulateurs synthétiques tels le THG-315, le THG-316 et MAREK a également été investiguée dans la même lignée cellulaire. Finalement, des surnageants d'hybridome 9H1/1C1, 9F5/1H4, 9F5/1H4, 9F5/1F8, 9F5/2B3 et 9F5/2E4 contenant des anticorps monoclonaux, dirigés tous contre un peptide qui équivaut à la région C-terminale de la troisième boucle extracellulaire du PAFR: GFQDSKfHQA ont également été utilisés, afin : (1) de déterminer le meilleur clone en terme d'affinité et de spécificité et (2) effectuer des tests pour savoir s'ils possèdent des propriétés agonistes ou antagonistes sur le PAFR. En conclusion, les résultats obtenus nous indiquent que : (1) l'efficacité des molécules orthostériques à antagoniser les réponses induites par le PAF dépend de leur nature et de leur concentration, (2) les modulateurs potentiellement allostériques utilisés ne modulent aucune des voies majoritairement connues pour être activées par le PAFR, et (3) qu'il n'y a aucun marquage spécifique du PAFR avec les surnageants d'hybridomes utilisés.

Activation orthostérique

GPCR (G protein coupled receptor)

PAF (platelet activating factor)

The Role of the Central Region of the Third Intracellular Loop of D1-Class Receptors in Signalling

Charrette, Andrew

17 July 2012

The D1-class receptors (D1R, D5R) each possess distinct signaling characteristics; however, pharmacological selectivity between them remains elusive. The third intracellular loops (IL3) of D1R and D5R harbour divergent residues that may contribute to their individual signalling phenotypes. Here we probe the function of central region of IL3 of D1R and D5R using deletion mutagenesis. Radioligand binding and whole cell cAMP assays suggest that the N-terminal and C-terminal moieties of the central IL3 oppositely contribute to the constitutive and agonist-dependant activity of D1-Class receptors. Whereas the N-terminal deletions ablated constitutive activity and decreased DA-induced activation, C-terminal deletions induced robust increases. These data, interpreted in concert with structural predictions generated from homology modeling implicate the central IL3 as playing an important role in the activation and subtype-specific characteristics of the D1-class receptors. This study may serve as a basis for the development of novel drugs targeting the central IL3 region.

G protein-coupled receptor

GPCR

Dopamine

D1

D5

homology model

deletion

third intracellular loop

D1-class receptor

Biophysical and magnetic resonance studies of membrane proteins

Orwick, Marcella Christine

January 2011

Bacteriorhodopsin (bR) is a 7TM membrane protein expressed in Halobacterium salinarum. Due to its stability and high expression levels, bR serves as a model for other 7TM membrane proteins. Neurotensin receptor 1 (NTS1) is a member of pharmacologically relevant G protein-coupled receptor superfamily, and is the high affinity receptor for neurotensin, a 13mer peptide that can be found in the brain, gut, and central nervous system. NTS1 is a target for Parkinson’s, Schizophrenia, and drug addiction. This thesis aims to develop pulsed magnetic resonance techniques and sample preparation forms for high resolution structural studies on 7TM proteins. In this thesis, pulsed dipolar distance electron paramagnetic resonance (EPR) methods for the study of proteins in their native membrane are established. bR is spin-labeled, and a wellresolved distance distribution is measured in excellent agreement with other structural data. Preliminary distance data for a photoexcited state of bR suggests quaternary rearrangements in the native membrane that are agreement with published AFM results. A fitting method is developed to enable measurements of systems with rapid signal decay, a common feature in reconstituted systems studied by pulsed EPR methods. A physical chemical characterization of nanosized-bilayer discs termed Lipodisqs®, and the successful incorporation of bR is presented. Lipodisqs® are formed from DMPC and a polymer that is able to solubilize DMPC vesicles into discrete particles. Lipodisqs® possess a broad phase transition with increased lipid ordering compared to a DMPC dispersion. The SMA polymer interacts with the lipid tails, but does not perturb the headgroup. BR is incorporated in the monomeric form, and EPR dynamic and distance measurements confirm that Lipodisqs® preserve the native structure of bR, whilst detergent solubilisation increases the overall mobility compared to bR in its native membrane, suggesting that Lipodisqs® serve as an excellent medium for EPR studies on 7TM membrane proteins. A cysteine-depleted mutant of active, ligand binding NTS1 is constructed. Cysteines are reintroduced at positions that may be able to monitor agonist and inverse-agonist induced conformational and dynamic changes. A spin-labeling protocol is developed, and preliminary EPR measurements are discussed. Dynamic nuclear polarization (DNP) results are presented with uniformly-¹³C-labelled bR in the PM, resulting in a DNP enhancement of 16 using the biradical nitroxide polarizing agent, TOTAPOL. DNP-enhanced solid state NMR (ssNMR) is typically carried out at cryogenic temperatures, resulting in poor spectral resolution compared to ambient temperatures. Two different forms of samples are prepared that could potentially lead to better-resolved DNP spectra. BR is reverse labelled by adding natural abundance amino acids to isotopically labelled growth medium, resulting in the partial depletion of resonance signals that may obscure and crowd the NMR spectra. A crystalline sample of bR is prepared using the LCP method for crystallization, which is to date the most successful method for the crystallization of GPCRs. In summary, the first pulsed dipolar measurements of a protein in its native membrane are shown, Lipodisqs® are characterized and found to be a suitable medium for structural and functional studies of 7 TM membrane proteins, the first preliminary EPR studies on a ligand binding GPCR are presented, and novel sample preparation techniques are developed for the nitroxide-based DNP enhancement of ssNMR data. This thesis opens up several avenues for future research into 7TM membrane proteins.

572.696

Multiplexed cell-based assays to profile GPCR activities and cellular signalling

Galinski, Sabrina

25 February 2016

No description available.

570

G protein-coupled receptor

GPCR

cell-based

molecular barcode

multiplexed assay

receptor activation

downstream signalling

Biologie (PPN619462639)

PHARMACOLOGICAL IMPLICATIONS OF ADENOSINE 2A RECEPTOR- DOPAMINE TYPE 2 RECEPTOR HETEROMERIZATION

Hatcher-Solis, Candice N

01 January 2016

G protein-coupled receptors (GPCRs) are heptahelical, transmembrane proteins that mediate a plethora of physiological functions by binding ligands and releasing G proteins that interact with downstream effectors. GPCRs signal as monomers, complexes of the same receptor subtype (homomers), or complexes of different receptor subtypes (heteromers). Recently, heteromeric GPCR complexes have become attractive targets for drug development since they exhibit distinct signaling and cell-specific localization from their homomeric counterparts. Yet, the effect of heteromerization on the pharmacology of many GPCR homomers remains unknown. Therefore, we have undertaken the task to examine the effect of heteromerization on Gs signaling through the adenosine 2A receptor (A2AR) and Gi signaling through the dopamine type 2 receptor (D2R) since the A2AR-D2R heteromer is an emerging therapeutic target for Parkinson’s disease (PD). We examined the effect of heteromerization on A2AR and D2R homomeric signaling using electrophysiology and the Xenopus laevis oocyte heterologous expression system. G protein-coupled inwardly rectifying potassium channels (GIRKs) were used as reporters for Gi signaling because activation leads to direct Gbeta-gamma (Gβγ)-mediated stimulation of the GIRK current. We also coupled GIRK channels to Gs signaling by overexpressing Gαs and signaling throughGαsβγ. Our electrophysiological assay is innovative because it allows us to optimize the conditions of heteromerization and directly observe GPCR signaling at the G protein level. Our data demonstrate that heteromer formation alone decreases dopamine-elicited Gi signaling through the D2R and CGS-21680-elicited Gs signaling through the A2AR. Furthermore, this reciprocal antagonism was predominately due to changes in efficacy versus potency. We also examined crosstalk observing that applying agonists or antagonists to the adjacent receptor further modulate this inhibition with the combination of agonists and antagonists relieving inhibition. Mutating the A2AR-D2R heteromer interface abrogated all of the aforementioned ligand-induced effects on G protein signaling through the A2AR-D2R heteromer. We are currently aiming to validate our results from the oocyte experiments with an in vivo model. Our data further elucidate the effect of various ligands on G protein signaling through the A2AR- D2R heteromer, which may facilitate future studies that examine A2AR-D2R heteromer signaling.

G-protein coupled-receptor

G protein Signaling

Heteromerization

Adenosine 2A Receptor

Dopamine D2 Receptor

Parkinson's disease

Medical Sciences

New C-C chemokine receptor type 7 antagonists

Ahmed, Mohaned S. A.

January 2016

Chemokines are chemotactic cytokines which play an important role in the migration of immune cells to distant tissues or compartments within tissues. These proteins have also been demonstrated to play a major role in cancer metastasis. The C-C chemokine receptor type 7 (CCR7) is a member of the chemokine receptor family. CCR7 along with its ligands CCL19 and CCL21 plays an important role in innate immune response by trafficking of lymphocytes. In cancer, tumour cells expressing CCR7 migrate to lymphoid organs and thus disseminate to other organs. Neutralizing the interactions between CCL21/CCR7 would therefore be expected to inhibit the progression and metastasis of many different types of cancer to regional lymph nodes or distant organs. Our objective was to identify a potent small molecule antagonist of CCR7 as a prelude to the investigation of the role of this axis in cancer metastasis. In this study, we provided a brief description of chemokines and their role in health and disease with an emphasis on the CCR7/CCL19/CCL21 axis, as well as identification of a CCR7 antagonist “hit”. The potency of the CCR7 antagonist “hit” was optimised by synthesizing different CCR7 antagonist analogues. The “hit” optimization process has led to discover the most active compound amongst a series of different analogues which have the ability to bind and block CCR7 receptor. The efficacy of the most active compound and other analogues were evaluated in vitro using a calcium flux assay which is based on detecting fluorescent light emitted upon release of calcium ions. To identify a suitable cell line, which expresses CCR7 and capably respond to it, amongst a panel of cell lines for in vitro assessment of potency of synthesised compounds, we used Western blot assay and later by flow cytometry assay. The activity and selectivity of the most effective compound against CCR7 receptor was evaluated in vitro by other functional assays such as “configured agarose spot assay” and scratch assay. We first configured the existing under agarose assay to fulfil our requirements and then used it to assess activity and selectivity of compounds. The configured agarose spot assay also describes the application of the agarose spot for evaluation of cells chemotactic response to multiple chemokines under identical experiment conditions.

616.99

Investigation on Pre- and Postsynaptic Ca²⁺Signaling in Neuronal Model Systems

Krjukova, Jelena

January 2004

<p>Communication between neuronal and non-neuronal is called volume transmission when the released neurotransmitter (NT) acts via diffusion and affects several target cells. Both the neurosecretory and postsynaptic cell responses are linked to [Ca²⁺]_i elevations. </p><p>In the present thesis the role of pre-and postsynaptic Ca²⁺ elevations has been investigated in the reconstituted "synapse" model comprised of NGF-differentiated PC12 and HEL cells as well as in SH-SY5Y neuroblastoma cells. In PC12 cells, both 70mM K⁺ and nicotine triggered NT release, which could be detected as a secondary [Ca²⁺]_i increase in surrounding HEL cells. Both secretagogues shared the same voltage-dependent Ca²⁺ influx pathway as judged from the pharmacological profile blockers of voltage-gated Ca²⁺ channels. The coupling of electrical responses to the activation of Ca²⁺ signaling via muscarinic receptors in SH-SY5Y cells was also studied. These data revealed that depolarization caused a considerable potentiation of the muscarinic Ca²⁺ response. The potentiated Ca²⁺ increase was mainly dependent on the enhanced Ca²⁺ influx and to a lesser extent on [Ca²⁺]_i release from intracellular stores. A phospholipase C (PLC) activator, m-3M3FBS was used to further study the role of G-protein coupled receptor (GPCR)-coupled Ca²⁺ signaling. However, it was found that m-3M3FBS instead triggered [Ca²⁺]_i elevations independently of PLC activation. </p><p>In conclusion, the results indicate that the magnitude of NT release from PC12 cells is sufficient to cause a robust activation of neighboring target cells. Postsynaptic muscarinic signaling is amplified due to integration of electrical excitation and GPCR signaling. The PLC activator, m-3M3FBS is not suitable for studies of PLC-mediated signals in intact cells.</p>

Physiology

calcium

neurotransmitter release

nicotine

depolarization

G-protein coupled receptor

muscarinic

phospholipase C

m-3M3FBS

Fysiologi

Physiology

Fysiologi

Functional Studies of the Neuropeptide Y System : Receptor-Ligand Interaction and Regulation of Food Intake

Åkerberg, Helena

January 2009

The members of the mammalian neuropeptide Y family, i.e. the peptides neuropeptide Y (NPY), peptide YY (PYY) and pancreatic polypeptide (PP), are all involved in regulation of food intake. In human and most other mammals they act via receptors Y1, Y2, Y4 and Y5. NPY is released in the hypothalamus and is one of the strongest appetite-stimulating neurotransmitters whereas PP and PYY are secreted from gut endocrine cells after meals and function as appetite-reducing hormones. This thesis describes studies of the NPY system at both the molecular and the physiological level. The first part describes two investigations of receptor-ligand interactions with the human Y1 and Y2 receptors. The results clarify the importance of several amino-acid residues of the human Y1 receptor. Three amino acids previously suggested by others to form a binding pocket for the carboxy-terminus of the peptide were confirmed to be crucial for interaction with peptide ligands. However, they were found to be too distantly located from each other to be able to form a binding pocket. Further investigation of the three corresponding positions in the human Y2 receptor showed that only one of the positions was important for interaction with full-length peptides. The results indicate overlapping but, surprisingly, non-identical binding of the different peptides to human Y1 and Y2 receptors, despite the fact that the two receptors share a common ancestor. The second part of the thesis describes an investigation of the effect of PP on food intake in six beagle dogs and a test for personality characteristics in dogs (TFPC). Treatment with physiological doses of PP decreased both the appetitive and the consummatory drive but had no effect on the amount food consumed. The TFPC protocol was used to map individual behavioral differences in a population of sixteen beagle dogs. The test, which included several situations that may appear in an experimental study, revealed considerable inter-individual differences in behavioral responses despite the fact that the dogs were born and housed in the same animal facility in constant controlled conditions. These results demonstrate that PP can influence food intake in distantly related mammals and emphasize the importance of considering differences in personality in experimental animals.

neuropeptide Y

G-protein coupled receptor (GPCR)

site-directed mutagenesis

pancreatic polypeptide

food intake

dog

Pharmacology

Farmakologi

Investigation on Pre- and Postsynaptic Ca2+ Signaling in Neuronal Model Systems

Krjukova, Jelena

January 2004

Communication between neuronal and non-neuronal is called volume transmission when the released neurotransmitter (NT) acts via diffusion and affects several target cells. Both the neurosecretory and postsynaptic cell responses are linked to [Ca2+]i elevations. In the present thesis the role of pre-and postsynaptic Ca2+ elevations has been investigated in the reconstituted "synapse" model comprised of NGF-differentiated PC12 and HEL cells as well as in SH-SY5Y neuroblastoma cells. In PC12 cells, both 70mM K+ and nicotine triggered NT release, which could be detected as a secondary [Ca2+]i increase in surrounding HEL cells. Both secretagogues shared the same voltage-dependent Ca2+ influx pathway as judged from the pharmacological profile blockers of voltage-gated Ca2+ channels. The coupling of electrical responses to the activation of Ca2+ signaling via muscarinic receptors in SH-SY5Y cells was also studied. These data revealed that depolarization caused a considerable potentiation of the muscarinic Ca2+ response. The potentiated Ca2+ increase was mainly dependent on the enhanced Ca2+ influx and to a lesser extent on [Ca2+]i release from intracellular stores. A phospholipase C (PLC) activator, m-3M3FBS was used to further study the role of G-protein coupled receptor (GPCR)-coupled Ca2+ signaling. However, it was found that m-3M3FBS instead triggered [Ca2+]i elevations independently of PLC activation. In conclusion, the results indicate that the magnitude of NT release from PC12 cells is sufficient to cause a robust activation of neighboring target cells. Postsynaptic muscarinic signaling is amplified due to integration of electrical excitation and GPCR signaling. The PLC activator, m-3M3FBS is not suitable for studies of PLC-mediated signals in intact cells.

Physiology

calcium

neurotransmitter release

nicotine

depolarization

G-protein coupled receptor

muscarinic

phospholipase C

m-3M3FBS

Fysiologi

Physiology

Fysiologi