Functional relevance of naturally occurring mutations in adhesion G protein-coupled receptor ADGRD1 (GPR133)

Fischer, Liane, Wilde, Caroline, Schöneberg, Torsten, Liebscher, Ines

January 2016

Background: A large number of human inherited and acquired diseases and phenotypes are caused by mutations in G protein-coupled receptors (GPCR). Genome-wide association studies (GWAS) have shown that variations in the ADGRD1 (GPR133) locus are linked with differences in metabolism, human height and heart frequency. ADGRD1 is a Gs protein-coupled receptor belonging to the class of adhesion GPCRs. Results: Analysis of more than 1000 sequenced human genomes revealed approximately 9000 single nucleotide polymorphisms (SNPs) in the human ADGRD1 as listed in public data bases. Approximately 2.4 % of these SNPs are located in exons resulting in 129 non-synonymous SNPs (nsSNPs) at 119 positions of ADGRD1. However, the functional relevance of those variants is unknown. In-depth characterization of these amino acid changes revealed several nsSNPs (A448D, Q600stop, C632fs [frame shift], A761E, N795K) causing full or partial loss of receptor function, while one nsSNP (F383S) significantly increased basal activity of ADGRD1. Conclusion: Our results show that a broad spectrum of functionally relevant ADGRD1 variants is present in the human population which may cause clinically relevant phenotypes, while being compatible with life when heterozygous.

info:eu-repo/classification/ddc/572

ddc:572

Structure, Function and Dynamics of G-Protein coupled Receptors

Eichler, Stefanie

26 January 2012

Understanding the function of membrane proteins is crucial to elucidate the molecular mechanisms by which transmembrane signaling based physiological processes,i. e., the interactions of extracellular ligands with membrane-bound receptors, are regulated. In this work, synthetic transmembrane segments derived from the visual photoreceptor rhodopsin, the full length system rhodopsin and mutants of opsin are used to study physical processes that underlie the function of this prototypical class-A G-protein coupled Receptor. The dependency of membrane protein hydration and protein-lipid interactions on side chain charge neutralization is addressed by fluorescence spectroscopy on synthetic transmembrane segments in detergent and lipidic environment constituting transmembrane segments of rhodopsin in the membrane. Results from spectroscopic studies allow us to construct a structural and thermodynamical model of coupled protonation of the conserved ERY motif in transmembrane helix 3 of rhodopsin and of helix restructuring in the micro-domain formed at the protein/lipid water phase boundary. Furthermore, synthesized peptides and full length systems were studied by time resolved FTIR-Fluorescence Cross Correlation Hydration Modulation, a technique specifically developed for the purpose of this study, to achieve a full prospect of time-resolved hydration effects on lipidic and proteinogenic groups, as well as their interactions. Multi-spectral experiments and time-dependent analyses based on 2D correlation where established to analyze large data sets obtained from time-resolved FTIR difference spectra and simultaneous static fluorescence recordings. The data reveal that lipids play a mediating role in transmitting hydration to the subsequent membrane protein response followed by water penetration into the receptor structure or into the sub-headgroup region in single membrane-spanning peptides carrying the conserved proton uptake site (monitored by the fluorescence emission of hydrophobic buried tryptophan). Our results support the assumption of the critical role of the lipid/water interface in membrane protein function and they prove in particular the important influence of electrostatics, i. e., side chain charges at the phase boundary, and hydration on that function. / Für die Aufklärung der molekularen Wirkungsweise von physiologischen, auf Signaltransduktion, d. h. dem Zusammenspiel von extrazellulären Reizen und membrangebundenen Rezeptoren, beruhenden Prozessen ist das Verständnis der Funktion von Membranproteinen unerlässlich. In dieser Arbeit werden von Rhodopsin abgleitete, synthetische transmembrane Segmentpeptide, Opsin-Mutanten und der vollständige Photorezeptor Rhodopsin untersucht, um die physikalischen Prozesse zu beleuchten, die der Funktionen dieses prototypischen Klasse-A G-Protein gekoppelten Rezeptors zugrunde liegen. Die Abhängigkeit der Membranprotein-Hydratation und der Lipid-Protein-Wechselwirkung von der Ladung einer Aminosäuren-Seitenkette wird erforscht. Hierzu werden synthetische, transmembrane Segmentpeptide in Lipid und Detergenz, als Modell transmembraner Segmente von Rhodopsin in der Membran mittels Fluoreszenzspektroskopie untersucht. Aus den erhaltenen Ergebnissen wird ein thermodynamisches und strukturelles Modell hergeleitet, welches die Kopplung der Protonierung des hochkonservierten ERY-Motivs in Transmembranhelix 3 von Rhodopsin an die Restrukturierung der Helix in der Mikroumgebung der Lipid-Wasser-Phasengrenze erklärt. Des Weiteren werden sowohl die Segementpeptide als auch die vollständigen Systeme Opsin und Rhodopsin mittels zeitaufgelöster FTIR-Fluoreszenz-Kreuzkorrelations-Hydratations-Modulation untersucht. Diese Technik wurde eigens zur Aufklärung von zeitabhängigen Hydratationseffekten auf Lipide und Proteine oder Peptide entwickelt. Dabei werden zeitaufgelöste FTIR Differenz-Spektren und gleichzeitig statische Fluoreszenzsignale aufgenommen und diese zeitabhängigen multispektralen Datensätze mittels 2D Korrelation analysiert. Die Auswertung der Experimente enthüllt einen sequentiellen Hydratationsprozess. Dieser beginnt mit der Bildung von Wasserstoffbrückenbindungen an der Carbonylgruppe des Lipids, gefolgt von Strukturänderungen der Transmembranproteine und abgeschlossen durch das Eindringen von Wasser in das Proteininnere. Letzteres wird nachgewiesen durch die Fluoreszenz von Tryptophan im hydrophoben Peptid- oder Proteininneren. Die Ergebnisse dieser Arbeit unterstreichen die Annahme, dass Lipid-Protein-Wechselwirkungen eine entscheidende Rolle in der Funktion von Membranproteinen spielen und das insbesondere Elektrostatik, in Form von Ladungen an der Phasengrenze, und die Hydratisierung einen kritischen Einfluss auf diese Funktion haben.

info:eu-repo/classification/ddc/570

ddc:570

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)

Regulation of Pancreatic α and β Cell Function by the Bile Acid Receptor TGR5

Prasanna Kumar, Divya

01 January 2014

The discovery that bile acids act as endogenous ligands of the membrane receptor TGR5 and the nuclear receptor FXR increased their significance as regulators of cholesterol, glucose and energy metabolism. Activation of TGR5, expressed on enteroendocrine L cells, by bile acids caused secretion of GLP-1, which stimulates insulin secretion from pancreatic β cells. Expression of TGR5 on pancreatic islet cells and the direct effect of bile acids on the endocrine functions of pancreas, however, are not fully understood. The aim of this study was to identify expression of TGR5 in pancreatic islet cells and determine the effect of bile acids on insulin secretion. Expression of TGR5 was identified by quantitative PCR and western blot in islets from human and mouse, and in α (αTC1-6) and β (MIN6) cells. Release of insulin, glucagon and GLP-1 were measured by ELISA. The signaling pathways coupled to TGR5 activation were identified by direct measurements such as stimulation of G proteins, adenylyl cyclase activity, PI hydrolysis and intracellular Ca2+ in response to bile acids; and confirmed by the use of selective inhibitors that block specific steps in the signaling pathway. Our studies identified expression of TGR5 receptors in β cells and demonstrated that activation of these receptors by both pharmacological ligands (oleanolic acid (OA) and INT-777) and physiological ligand (lithocholic acid, LCA) induced insulin secretion. TGR5 receptors are also expressed in α cells and, activation of TGR5 by OA, INT-777 and LCA at 5 mM glucose induced release of glucagon, which is processed from proglucagon by the selective expression of prohormone convertase 2 (PC2). However, under hyperglycemia, activation of TGR5 in α cells augmented the glucose-induced increase in GLP-1 secretion, which in turn, stimulated insulin secretion. Secretion of GLP-1 from α cells reflected TGR5-mediated increase in PC1 promoter activity and PC1 expression, which selectively converts proglucagon to GLP-1. The signaling pathway activated by TGR5 to mediate insulin and GLP-1 secretion involved Gs/cAMP/Epac/PLC-ε/Ca2+. These results provide insights into the mechanisms involved in the regulation of pancreatic α and β cell function by bile acids and may lead to new therapeutic avenues for the treatment of diabetes.

Bile acids

TGR5 receptors

INT-777

Oleanolic acid

G-protein coupled receptors

incretins

Cellular and Molecular Physiology

Endocrinology

Úloha receptorů spřažených s Gq proteiny v hnědých adipocytech / Role of Gq-coupled receptors in brown adipocytes

Čajková, Michaela

January 2015

Charles university in Prague, Pharmaceutical faculty in Hradci Králové, Department of biological and medical sciences Rheinische Friedrich-Wilhelms-University Bonn, Institute of Pharmacology and Toxicology Candidate: Michaela Čajková Supervisor: PharmDr. Miroslav Kovařík, Ph.D. Consultant: Dr. Linda Sarah Hoffmann Title of diploma thesis: Role of Gq-coupled receptors in brown adipocytes In my diploma thesis, we focused on four Gq-coupled receptors (F2R, LPHN1, α1DAR, TSHR) in brown adipocytes (BAs), which were identified in the screen as the highest expressed in immature and mature BAs. Our goal was to validate suggestion, that Thyroid stimulating hormone receptor (TSHR) plays a key role in differentiation of BAs and that F2R, LPHN1, α1D-AR might be important for BAs. In our study, we investigated gene expression of these four receptors in BAs, using analytical methodsquantitative reverse-transcriptase polymerase chain reaction (qRT-PCR) and Western blot. Results from analysis revealed, that expression of TSHR was increased in mature BAs, it means, that TSHR induce differentiation of BAs. The BAs transduced with short hairpin RNA (sh-RNA) against TSHR were less differentiated, this we proved also with Oil Red-O staining. Expression of adipocyte Protein 2 (aP2), peroxisome proliferator-activated...

Postnatální vývoj GABAb-receptorů v přední mozkové kůře potkana / Postnatal development of GABAb-receptors in the frontal rat brain cortex

Kagan, Dmytro

January 2015

In this work, the detailed analysis of GABAB-R/G protein coupling in the course of pre- and postnatal development of rat brain cortex indicated the significant intrinsic efficacy of GABAB-receptors already shortly after the birth: at postnatal day 1 and 2. Subsequently, both baclofen and SKF97541-stimulated G protein activity, measured as the high-affinity [35 S]GTPγS binding, was increased. The highest level of agonist-stimulated [35 S]GTPγS binding was detected at postnatal days 14 and 15. In older rats, the efficacy, i.e. the maximum response of baclofen- and SKF97541-stimulated [35 S]GTPγS binding was continuously decreased so, that the level in adult, 90-days old rats was not different from that in newborn animals. The potency of G protein response to baclofen stimulation, characterized by EC50 values, was also high at birth but unchanged by further development. The individual variance among the agonists was observed in this respect, as the potency of SKF97541 response was decreased when compared in 2-days old and adult rats. The highest plasma membrane density of GABAB-R, determined by saturation binding assay with specific antagonist [3 H]CGP54626AA, was observed in 1-day old animals. The further development was reflected in decrease of receptor number. The adult level was ≈3- fold lower than...

Characterization of two domains of Schizosaccharomyces pombe adenylate cyclase

Baum, Kristen Michelle

January 2005

Thesis advisor: Charles S. Hoffman / Glucose detection in yeast occurs via a cAMP signaling pathway that is similar to that of other signaling pathways in humans. The presence of glucose in the environment ultimately represses, as a result of cAMP signaling, the transcription of the gene fbp1. Adenylate cyclase is known to convert ATP to cAMP, and is thus a central protein in the propagation of the signal. Mutant forms of the adenylate cyclase gene (git2) have been found by the inability for the organism to repress fbp1 transcription in the presence of glucose. In this study, two questions were under investigation. The first was focused on the ability of the mutations to affect the dimerization of the catalytic domain. The second investigated multiple protein-protein interactions in the leucine rich-repeat (LRR) domain of adenylate cyclase. Both domains contain mutations that confer an activation defect, and they are thus are thought to have a relationship. / Thesis (BS) — Boston College, 2005. / Submitted to: Boston College. College of Arts and Sciences. / Discipline: Biology. / Discipline: College Honors Program.

Biology, Genetics

adenylate cyclase

Schizosaccharomyces pombe

leucine rich repeat

cAMP signaling

G-protein signaling

two-hybrid screen