Expression, Purification and Crystallisation Studies with the M2 Muscarinic and H1 Histamine Receptors.

Aloia, Amanda Louise, amanda.aloia@hotmail.com

January 2008

This thesis describes the expression of three human seven transmembrane receptors: the M2 Muscarinic; H1 Histamine and 5HT2A Serotonin receptors, in the baculovirus/insect cell expression system. Purification trials werre conducted on the M2 Muscarinic and H1 Histamine receptors. Preliminary crystallisation attempts were made with the H1 receptor.

GPCR

G-protein

seven transmembrane receptor

baculovirus

expression

purification.

Récepteurs de la mélatonine : pharmacologie du récepteur ovin MT2, identification de leur activité constitutive et développement d'une approche par ARN interférent. / Melatonin receptors : pharmacology of ovine MT2 receptor, identification of constitutive activity and development of interfering RNA

Devavry, Severine

19 December 2011

La mélatonine est une hormone synthétisée et sécrétée uniquement la nuit par la glande pinéale. Son rôle principal est son implication dans la synchronisation de la saison de reproduction. La mélatonine se lie aux récepteurs, MT1 et MT,, membres de la famille des récepteurs à sept domaines transmembranaires couplés aux protéines G (RCPG).Le clonage récent du récepteur ovin MT2a remis en cause toutes les données connues. La pharmacologie et les voies de signalisation du récepteur oMT2ont été étudiées et sont communes à celles des récepteurs des autres espèces. En revanche, oMT2possède une originalité de séquence avec la présence du motif DRY, fortement impliqué dans l’établissement de l’activité constitutive des RCPG. D’une part, nous avons montré que l’ensemble des récepteurs MT possèdent une activité constitutive. D’autre part, nous avons identifié deux agonistes inverses pour les récepteurs hMT2, initialement décrits comme antagonistes. Dans l’optique de discriminer les rôles respectifs des récepteurs MT in vivo, le développement d’une approche par ARN interférents a été validée dans un modèle cellulaire, la lignée CHO-KI exprimant les récepteurs ovins et de rat. / Melatonin is a hormone synthesized and secreted only during night by pineal gland. A main role of melatoninconcerns its implication in the synchronization of reproductive seasonality. Binding sites of melatonin are MT1and MT2 receptors which belong to the superfamily of seven-transmembrane-spanning G protein-coupledreceptors (GPCRs).Recent cloning of ovine MT2 receptor has challenged the knowledge about melatonin receptors. Wedemonstrated that its pharmacology and signalling pathways were similar to subtype 2 receptor of othersspecies (human and rat). Nevertheless, oMT2 receptor possesses a particularity of sequence, with the presenceof DRY motif which is known to be involved in the establishment of constitutive activity of GPCRs. In ourstudy, we demonstrated the existence of constitutive activity for ail the melatonin receptors. In addition, weidentified two inverse agonists for human MT2 receptors, previously described as antagonists. To describe therespective roles of each subtype of melatonin receptors in vivo, siRNA approach was developed in cell line,CI-10-K Iexpressing ovine and rat melatonin receptors

Récepteur ovin MT2

Melatonin

GPCR

Ovine

Inverse agonists

SiRNA

Molecular mechanisms of Hedgehog signal transduction by the G-protein coupled receptor smoothened

Byrne, Eamon

January 2017

The Hedgehog signalling pathway is an essential developmental pathway present in all bilaterians that is involved in embryogenesis, body patterning and stem cell homeostasis. Dysregulation of the Hh pathway leads to various kinds of cancer, such as basal cell carcinoma and medulloblastoma. Smoothened (SMO), a Frizzled-type G-protein coupled receptor (GPCR), is the essential transmembrane signal transducer within the Hh pathway, conveying the signal from the upstream transmembrane protein, Patched1 (Ptc1), to the downstream intracellular proteins. The mechanisms by which SMO transmits the Hh signal from the extracellular environment, through the plasma membrane and to the intracellular proteins are not known. In this thesis, I present my work into the structural and functional characterisation of the extracellular and transmembrane domains (TMD) of human SMO in order to better understand the molecular mechanisms of its signal transduction. The extracellular region of SMO contains a highly conserved cysteine-rich domain (CRD) and a linker domain (LD). I present the first crystal structure of the CRD, LD and TMD of SMO, which is also the first crystal structure of a GPCR with a large functional extracellular domain. This structure revealed a domain architecture for SMO that enables regulation of its transmembrane domain by its extracellular domains. It also revealed a cholesterol molecule bound to the CRD, which we subsequently determined to be a new endogenous small-molecule agonist for SMO. I present five further structures of SMO bound to different small molecule agonists and antagonists. Together, these structures demonstrate that the position of the CRD relative to the TMD reflects the activation state of SMO. We also generated nanobodies against the extracellular region of SMO in order to stabilise its conformation. These studies not only improve our understanding of the workings of a key transmembrane protein within a fundamental signalling pathway but will also aid efforts to develop better therapeutics for an important cancer target.

Thermostabilisation of the human CRF1 receptor in the presence of an agonist and a G protein

Strege, Annette

January 2018

No description available.

Functional regulation of kisspeptin receptor by calmodulin and Ca2+/calmodulin-dependent protein kinase II

Jama, Abdirahman Mohamud

January 2015

The kisspeptin receptor (KISS1R), functioning as a metastasis suppressor and gatekeeper of GnRH neurons, is a potent activator of intracellular Ca2+. The surge in cytoplasmic Ca2+ mediates the exocytosis of GnRH from GnRH neurons. However, the regulatory processes which enable KISS1R to sense increasing intracellular Ca2+ and avoid Ca2+ excitotoxicity via a signalling off-switch mechanism remain unclear. This thesis provides evidence for the interaction between KISS1R and the Ca2+ regulated proteins of calmodulin (CaM), and αCa2+/CaM-dependent-protein kinase II (α-CaMKII). Binding of CaM to KISS1R was shown with three independent approaches. Firstly, cell-free spectrofluorimeter assays showed that CaM selectively binds to intracellular loop (IL) 2 and IL3 of the KISS1R. Secondly, KISS1R co-immunoprecipitation experiments identified ligand/Ca2+-dependent binding of KISS1R to HEK-293 endogenous CaM. Thirdly, confocal experiments showed CFPCaM co-localises with YFP-KISS1R. The functional relevance of CaM binding was examined with alanine substitution of critical residues of the CaM binding motifs in IL2 and IL3 of KISS1R. This approach revealed that the receptor activity (relative maximum responsiveness) was increased in the mutated residues of the juxtamembrane regions of IL3 and the N-terminus of IL2 relative to wild-type KISS1R. The Ca2+/CaM regulated αCaMKII was also found to interact with KISS1R by selectively phosphorylating T77 of IL1. Phosphomimetic mutations of T77 into E or D created a receptor that was unable to elicit inositol phosphate production upon ligand stimulation. Finally, in vivo studies using ovariectomised rats that were intracerebroventricularly administered with a cell-permeable αCaMKII inhibitor augmented the effects of kisspeptin ligand stimulation of plasma luteinizing hormone levels. Taken together, this thesis demonstrates that the KISS1R-G protein coupling is regulated by Ca2+-dependent CaM binding and αCaMKII-mediated KISS1R phosphorylation.

572

Assessing neuronal ciliary localization of Melanin Concentrating Hormone Receptor 1 in vivo

Kamba, Tisianna K.

08 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Obesity is a growing pandemic that claims close to three hundred thousand lives per year in the United States alone. Despite strong interest and investment in potential treatments, obesity remains a complex and challenging disorder. In the study of obesity, mouse models have been excellent tools that help in understanding the function of different genes that contribute to this disease of energy homeostasis. However, it was surprising when disfunction in primary cilia was found to be linked to syndromic obesity. To understand the role of primary cilia in obesity, a growing subset of GPCRs have been identified to selectively localize to the organelle. Several of which have known roles in energy homeostasis. In some examples, ciliary GPCRs appear to dynamically localize to the organelle; such is the case of GPR161 and smoothened in the hedgehog signaling pathway. Thus, we were interested to see if other GPCRs dynamically localize to the primary cilia as part of their regulation of energy homeostasis. For example, the GPCR MCHR1 selectively localizes to the cilia and is involved in energy homeostasis. Although much is known about the expression of the receptor in the brain, how its ciliary subcellular localization impacts its roles in energy homeostasis is unknown. Observing neuronal cilia in vivo remains a difficult task as some of the available tools such as tagged alleles rely on overexpression of ciliary protein which may impact function. Additionally, most of the work is done in vitro, leaving much to be discovered about neuronal cilia in vivo. In this thesis, we show that using a newly constructed reporter allele mCherryMCHR1, we can see ciliary expression of MCHR1 in the brain of developing and adult mice; more specifically in the ARC and PVN. Subsequently, using a novel Artificial intelligence analysis approach, we measured the length and composition of MCHR1 positive cilia under physiological conditions associated with MCHR1 function. Although in this work we are reporting no changes in dynamic localization of MCHR1 in the hypothalamus specifically, we are not excluding the potential for changes in other regions of the brain or under other conditions; and we are suggesting that pharmacological approaches may help highlight potential ciliary GPCR dynamic localization.

cilia

ciliary

obesity

Hh

HFD

Fasted

in vivo

MCHR1

GPCR

Host Signaling Response to Adhesion of Bifidobacterium infantis

Gann, Reed N.

01 May 2010

Investigations of the molecular binding partners of the probiotic bacterium Bifidobacterium longum subspecies infantis (B. infantis) and the pathogen Salmonella enterica subspecies enterica serovar Typhimurium LT2 (Salmonella ser. Typhimurium) found that these two very different bacteria bind gangliosides. However, these organisms lead to completely different host health outcomes when present in the gut. B. infantis is the founding microbial population in the intestinal tract of breast-fed infants. S. typhimurium is the most important food-borne pathogen that results in humans. This study used an in vitro gut epithelial cell model to examine the host cellular response to adhesion of B. infantis, which led to an increase in intestinal epithelium survival. This observation led to a series of experiments to elucidate the pathway for host signaling initiated by adherence of B. infantis to the host membrane to explain the increase in host cell survival. B. infantis adhesion induced significant (q≤0.05) differential expression of 208 host genes. These genes were associated with increased broad mechanisms of cell survival that included BIRC3, TNFAIP3, and SERPINB9. We hypothesized that a biochemical link existed between the host membrane adhesion protein and the increase in cell survival, mediated via AKT. We tested this hypothesis to demonstrate that B. infantis interaction initiated signal transduction using G-proteins via phosphorylation of AKT and induced production of the BIRC3, TNFAIP3, and SERPINB9. This study discovered adhesion of B. infantis initiated activation of AKT via phosphorylation of both Ser473 and Thr308, which results in increased cell survival.

Bifidobacterium infantis

cell survival

cytotoxicity

GPCR

Microbiology

Molecular Biology

The dissection of the molecular mechanism underlying the facilitative action of prostaglandin E receptor EP1 on dopamine D1 receptor-induced cAMP production / ドパミンD1受容体によるcAMP産生におけるプロスタグランジンE受容体EP1の促進的作用を担う分子機構の解明

Aliza Toby Ehrlich

24 September 2013

京都大学 / 0048 / 新制・課程博士 / 博士(生命科学) / 甲第17931号 / 生博第294号 / 新制||生||38(附属図書館) / 30751 / 京都大学大学院生命科学研究科高次生命科学専攻 / (主査)教授 垣塚 彰, 教授 渡邉 大, 教授 松崎 文雄 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM

GPCR

heteromer

dopamine

prostaglandin

Gβγ

adenylyl cyclase

460

The Role of RhoA in GPR116 Mediated Alveolar Homeostasis

Lawder, John J.

04 November 2019

No description available.

Molecular Biology

RhoA

GPR116

Surfactant

GPCR

Lung

Actin

Analyses of HCMV Replication in Salivary Epithelial Cells: Contributions of vGPCR signaling and HDAC inhibition

Beucler, Matthew

23 August 2022

No description available.

Virology

HCMV

virus

epithelial cell

infection

GPCR

cytomegalovirus