Global ETD Search

141	Evolution of the Neuropeptide Y System in Vertebrates with Focus on Fishes Larsson, Tomas January 2007 (has links) <p>Gene families in vertebrates often contain more dulicates (paralogs) than in invertebrates. This has been attributed to genome duplications, i.e., tetraploidizations. Two of the gene families that have expanded in vertebrate evolution are the neuropeptide Y (NPY) family of peptides and the neuropeptide Y receptors (NPYR) that are involved in many brain functions including appetite regulation.</p><p>Two NPYR genes, Y2 and Y7, were cloned in the rainbow trout. Although they arose from a common ancestral gene in early vertebrate evolution, their ligand-binding properties are very similar. Two NPYR genes were cloned in the coelacanth <i>Latimeria chalumnae</i> and found to be orthologs of Y5 and Y6 discovered in mammals.</p><p>Analyses of gene families close to the NPYR genes in the pufferfishes <i>T. nigroviridis</i> and <i>T. rubripes</i> showed that at least 25 additional gene families had an evolutionary history similar to the NPYR family, thereby providing evidence for fish specific-duplications of these chromosomes. Cloning and phylogenetic analysis of 22 NPYR gene fragments from several ray-finned fishes showed that basal species seem to have the same repertoire as tetrapods. Despite the tetraploidization in the teleost fish lineage, many teleosts seem to have fever genes than the gnathostome ancestor due to gene loss. Only one duplicate seems to have survived.</p><p>The NPY peptide family was found to have expanded in the teleost tetraploidization with duplicates of both NPY and PYY (peptide YY) in some teleosts. Fourteen neighboring gene families were found to have evolved in a similar manner as the NPY-family genes. Positional information fascilitated orthology assignment of peptide genes in teleost fishes and allowed correction of previously misidentified genes.</p><p>In summary, the evolutionary history of the NPY and NPYR gene families involve large-scale duplication events coinciding with the proposed tetraploidizations. The appearance of new genes in early vertebrates and in teleost fishes probably had important implications for the evolution of new functions in this system.</p> Molecular biology neuropeptide Y GPCR evolution gene duplication vertebrates ray-finned fishes Molekylärbiologi
142	NOVEL CONSTITUTIVELY ACTIVE POINT MUTATIONS IN THE NH2 DOMAIN OF CXCR2 CAPTURE THE RECEPTOR IN DIFFERENT ACTIVATION STATES Park, Giljun 01 December 2010 (has links) Chemokines are structurally and functionally related 8-10 kDa proteins defined by four conserved cysteine residues. They consist of a superfamily of proinflammatory mediators that promote the recruitment of various kinds of leukocytes and other cell types through binding to their respective chemokine receptor, a member of the GPCR family. Abnormal control of this system results in various diseases including tumorigenesis and cancer metastasis. Deregulation can occur when constitutively active mutant (CAM) chemokine receptors are locked in the “on” position. This can lead to cellular transformation/tumorigenesis. A viral CAM receptor, ORF74, that can cause tumors in humans, also has homology to human CXC chemokine receptor 2 (CXCR2), which is a G-protein-coupled receptor (GPCR) expressed on neutrophils, some monocytes, endothelial cells, and some epithelial cells. CXCR2 activation with ELR+ CXC chemokines induces leukocyte migration, trafficking, cellular differentiation, angiogenesis and cellular transformation. Using a high throughput yeast screen we identified a novel point mutation, D9H, in CXCR2, which leads to constitutive activation (CA). Generation of positively charged substitutions, D9K and D9R, and D143V as a positive control resulted in CA CXCR2 with differential levels of cellular transformation. To further investigate how D9 mutations lead to differential CA, we used inhibitors of known signal transduction pathways. Pertusiss toxin (PTX) sensitivity in foci formation assays demonstrated that D9R uses the Gi subunit like WTCXCR2 and D143V, while D9H and D9K do not. All CA receptors use the JAK pathway based on sensitivity to the inhibitor, AG490. Phosphorylation of PLC-beta 3 and sensitivity to the PLC-beta 3 inhibitor, U73122, implicates that mutant receptors such as D143V, D9H, D9K, and D9R utilize the Gq/11 subunit. Interestingly, D9R use both Gi and Gq/11 subunits. All of the CA receptors induced phosphorylation of the epidermal growth factor receptor (EGFR) indicating a transactivation between CXCR2 and EGFR. These data describe two novel and important findings. First, N-terminal CXCR2 controls activation and signaling using multiple G protein subunits to elicit downstream signaling. Second, our work supports the “functional selectivity” model for GPCR activation. That is, mimicking agonist activation, CA CXCR2 receptors have multiple conformational states that lead to differential activation. GPCR G-protein Chemokine receptor CXCR2 signal transduction Biochemistry Cell Biology Molecular Biology
143	Charakterisierung der Serotonin-Rezeptoren in den Speicheldrüsen von Calliphora vicina / Characterization of serotonin receptors in the salivary gland of Calliphora vicina Röser, Claudia January 2012 (has links) Die Fähigkeit, mit anderen Zellen zu kommunizieren, ist eine grundlegende Eigenschaft aller lebenden Zellen und essentiell für die normale Funktionsweise vielzelliger Organismen. Die Speicheldrüsen der Schmeißfliege Calliphora vicina bilden ein ausgezeichnetes physiologisches Modellsystem um zelluläre Signaltransduktionsprozesse an einem intakten Organ zu untersuchen. Die Speichelsekretion wird dabei hormonell durch das biogene Amin Serotonin (5-Hydroxytryptamin; 5-HT) reguliert. 5-HT aktiviert in den sekretorischen Zellen der Drüsen über die Bindung an mindestens zwei membranständige G-Protein gekoppelte Rezeptoren (GPCR) zwei separate Signalwege, den IP3/Ca2+- und den cAMP-Signalweg. Zur Identifizierung und Charakterisierung der 5-HT-Rezeptoren in den Speicheldrüsen von Calliphora wurden unter Anwendung verschiedener Klonierungsstrategien zwei cDNAs (Cv5-ht2α und Cv5-ht7) isoliert, die große Ähnlichkeit zu 5-HT2- und 5-HT7-Rezeptoren aus Säugetieren aufweisen. Die Hydropathieprofile der abgeleiteten Aminosäuresequenzen postulieren die für GPCRs charakteristische heptahelikale Architektur. Alle Aminosäuremotive, die für die Ligandenbindung, die Rezeptoraktivierung und die Kopplung an G-Proteine essentiell sind, liegen konserviert vor. Interessanterweise wurde für den Cv5-HT7-Rezeptor eine zusätzliche hydrophobe Domäne im N Terminus vorhergesagt. Die Cv5-HT2α-mRNA liegt in zwei alternativ gespleißten Varianten vor. Mittels RT-PCR-Experimenten konnte die Expression beider Rezeptoren in Gehirn und Speicheldrüsen adulter Fliegen nachgewiesen werden. Ein Antiserum gegen den Cv5-HT7 Rezeptor markiert in den Speicheldrüsen die basolaterale Plasmamembran. Die Expression der Rezeptoren in einem heterologen System (HEK 293-Zellen) bestätigte diese als funktionelle 5-HT Rezeptoren. So führte die Stimulation mit Serotonin für den Cv5-HT2α zu einer dosis-abhängigen Erhöhung der intrazellulären Ca2+ Konzentration ([Ca2+]i, EC50 = 24 nM). In Cv5-HT7-exprimierenden Zellen löste 5-HT dosisabhängig (EC50 = 4,1 nM) einen Anstieg der intrazellulären cAMP Konzentration ([cAMP]i) aus. Für beide heterolog exprimierten Rezeptoren wurden pharmakologische Profile erstellt. Liganden, die eine Rezeptorsubtyp-spezifische Wirkung vermuten ließen, wurden daraufhin auf ihre Wirkung auf das transepitheliale Potential (TEP) intakter Speicheldrüsenpräparate getestet. Drei 5-HT-Rezeptoragonisten: AS 19, R-(+)-Lisurid und 5-Carboxamidotryptamin führten zu einer cAMP-abhängigen Positivierung des TEP durch eine selektive Aktivierung der 5 HT7-Rezeptoren. Eine selektive Aktivierung des Ca2+-Signalweges durch den Cv5-HT2 Rezeptor ist mit Hilfe von 5-Methoxytryptamin möglich. Dagegen konnte Clozapin im TEP als selektiver Cv5-HT7-Rezeptorantagonist bestätigt werden. Die Kombination eines molekularen Ansatzes mit physiologischen Messungen ermöglichte somit die Identifikation selektiver Liganden für 5-HT2- bzw. 5-HT7-Rezeptoren aus Calliphora vicina. Dies ermöglicht zukünftig eine separate Aktivierung der 5-HT-gesteuerten Signalwege und erleichtert dadurch die weitere Erforschung der intrazellulären Signalwege und ihrer Wechselwirkungen. / Cellular communication is a fundamental property of living cells and essential for normal functioning of multicellular organisms. The salivary glands of the blowfly Calliphora vicina are a well established physiological model system to study cellular signaling in an intact organ. Fluid secretion in this gland is hormonally regulated by the biogenic amine serotonin (5-hydroxytryptamine, 5-HT). In the secretory cells, 5-HT causes a parallel activation of the InsP3/Ca2+- and the cAMP-signaling pathways through binding and stimulation of at least two G protein coupled receptors (GPCR). In order to characterize the respective 5-HT receptors on the secretory cells, we have cloned two cDNAs (Cv5-ht2α, Cv5-ht7) that share high similarity with mammalian 5-HT2 and 5-HT7 receptor classes. Analysis of the deduced amino acid sequences postulates the typical heptahelical architecture of GPCRs for both receptors. Sequence motifs that are essential for ligand binding, receptor activation and coupling to G-proteins are well conserved. Interestingly, a computer-based structural analysis of Cv5-HT7 predicts an additional eighth hydrophobic region in the N-terminus of the receptor. We also found an alternative splice variant of the Cv5-HT2α mRNA. Using RT-PCR experiments, transcripts of both receptor mRNAs could be detected in brain and salivary gland tissue. An antiserum raised against the Cv5 HT7 receptor stained the basolateral region of the salivary glands. Heterologous receptor expression in HEK 293 cells leads to a dose-dependent increase in the intracellular Ca2+-concentration ([Ca2+]i) for Cv5-HT2α (EC50 = 24 nM) and cAMP-concentration for Cv5-HT7 (EC50 = 4,1 nM) upon application of 5-HT. A pharmacological profile was established for both receptors. Ligands that appeared to act as specific ligands of either Cv5-HT2α or Cv5-HT7 in this approach, were then tested for their effect on the transepithelial potential (TEP) of intact blowfly salivary gland preparations. Three 5-HT receptor agonists: AS 19, R-(+)-lisuride and 5-carboxamidotryptamine showed a cAMP dependent positivation of the TEP, caused by a selective activation of the Cv5-HT7 receptor. 5-methoxytryptamine exclusively activates the Ca2+ pathway via Cv5-HT2α. Clozapine antagonizes the effects of 5-HT in blowfly salivary glands and was confirmed as a Cv5-HT7 antagonist. The combination of a molecular approach with physiological measurements enabled us to identify selective ligands for 5-HT2 and 5-HT7 receptors of Calliphora vicina. These results facilitate a selective activation of the intracellular signaling pathways activated by 5-HT and will facilitate future research on different aspects of intracellular signaling and crosstalk mechanisms. Calliphora GPCR Serotonin Rezeptor zelluläre Signalübertragung Calliphora G-protein-coupled receptors serotonin cellular signalling Life sciences
144	Evolution of the Neuropeptide Y System in Vertebrates with Focus on Fishes Larsson, Tomas January 2007 (has links) Gene families in vertebrates often contain more dulicates (paralogs) than in invertebrates. This has been attributed to genome duplications, i.e., tetraploidizations. Two of the gene families that have expanded in vertebrate evolution are the neuropeptide Y (NPY) family of peptides and the neuropeptide Y receptors (NPYR) that are involved in many brain functions including appetite regulation. Two NPYR genes, Y2 and Y7, were cloned in the rainbow trout. Although they arose from a common ancestral gene in early vertebrate evolution, their ligand-binding properties are very similar. Two NPYR genes were cloned in the coelacanth Latimeria chalumnae and found to be orthologs of Y5 and Y6 discovered in mammals. Analyses of gene families close to the NPYR genes in the pufferfishes T. nigroviridis and T. rubripes showed that at least 25 additional gene families had an evolutionary history similar to the NPYR family, thereby providing evidence for fish specific-duplications of these chromosomes. Cloning and phylogenetic analysis of 22 NPYR gene fragments from several ray-finned fishes showed that basal species seem to have the same repertoire as tetrapods. Despite the tetraploidization in the teleost fish lineage, many teleosts seem to have fever genes than the gnathostome ancestor due to gene loss. Only one duplicate seems to have survived. The NPY peptide family was found to have expanded in the teleost tetraploidization with duplicates of both NPY and PYY (peptide YY) in some teleosts. Fourteen neighboring gene families were found to have evolved in a similar manner as the NPY-family genes. Positional information fascilitated orthology assignment of peptide genes in teleost fishes and allowed correction of previously misidentified genes. In summary, the evolutionary history of the NPY and NPYR gene families involve large-scale duplication events coinciding with the proposed tetraploidizations. The appearance of new genes in early vertebrates and in teleost fishes probably had important implications for the evolution of new functions in this system. Molecular biology neuropeptide Y GPCR evolution gene duplication vertebrates ray-finned fishes Molekylärbiologi
145	Identification, Characterization and Evolution of Membrane-bound Proteins Höglund, Pär J. January 2008 (has links) Membrane proteins constitute approximately 30% of all genes in the human genome and two large families of membrane proteins are G protein-coupled receptors (GPCRs) and Solute Carriers (SLCs) with about 800 and 380 human genes, respectively. In Papers I, II and IV, we report 16 novel human Adhesion GPCRs found by searches in NCBI and Celera databases. In Paper I, we report eight novel human GPCRs, and six in Paper II. We identified two new human Adhesion GPCRs and 17 mouse orthologs in Paper IV. Phylogenetic analysis demonstrates that the 16 novel human genes are additional members of the Adhesion GPCR family and can be divided into eight phylogenetic groups. EST expression charts for the entire repertoire of Adhesions in human and mouse were established, showing widespread distribution in both central and peripheral tissues. Different domains were found in their N-terminus, some, such as pentraxin in GPR112, indicates that they take part in immunological processes. In Paper III, we discovered seven new human Rhodopsin GPCRs. In Paper V, we present the identification of two new human genes, termed SLC6A17 and SLC6A18 from the Solute Carriers family 6 (SLC6). We also identified the corresponding orthologs and additional genes from the mouse and rat genomes. We analysed, in total, 430 unique SLC6 proteins from 10 animal, one plant, two fungi and 196 bacterial genomes. In Paper VI, we provide the first systematic analysis of the evolutionary history of the different SLC families in Eukaryotes. In all, we analysed 2403 sequences in eight species and we delineate the evolutionary history of each of the 46 SLC families. G protein-coupled receptor GPCR Solute Carriers SLC Bioinformatics Evolution Rhodopsin Adhesion Phylogeny Pharmacology Farmakologi
146	MonoAminergic Receptors in the Stomatogastric Nervous System: Characterization and Localization in Panulirus Interruptus Clark, Merry Christine 22 April 2008 (has links) Neural circuit flexibility is fundamental to the production of adaptable behaviors. Invertebrate models offer relatively simple networks consisting of large, identifiable neurons that are useful for investigating the electrophysiological properties that contribute to circuit output. In particular, central pattern generating circuits within the crustacean stomatogastric nervous system have been well characterized with regard to their synaptic connectivities, cellular properties, and response to modulatory influences. Monoaminergic modulation is essential for the production of adaptable circuit output in most species. Monoamines, such as dopamine and serotonin, signal via metabotropic receptors, which activate intracellular signaling cascades. Many of the neuronal and network targets of monoaminergic modulation in the crustacean stomatogastric nervous system are known, but nothing is known of the signal transduction cascades that mediate the biophysical response. This work represents a thorough characterization of monoaminergic receptors in the crustacean stomatogastric nervous system. We took advantage of the close phylogenetic relationship between crustaceans and insects to clone monoaminergic receptors from the spiny lobster. Using a novel database mining strategy, we were able to identify several uncharacterized monoaminergic receptors in the Panulirus interruptus genome. We cloned one serotonin (5-HT2βPan) and three dopamine receptors (D1αPan, D1βPan, and D2αPan), and characterized them with regard to G protein coupling and signal transduction cascades. We used a heterologous expression system to show that G protein couplings and signaling properties of monoaminergic receptors are strongly conserved among vertebrate and invertebrate species. This work further shows that DAR-G protein couplings in the stomatogastric nervous system are unique for a given receptor subtype, and receptors can couple to multiple signaling pathways, similar to their mammalian homologs. Custom made antibodies were used to localize monoamine receptors in the stomatogastric ganglion, and in identified neurons. Pyloric neurons show unique receptor expression profiles, which supports the idea of receptor expression as an underlying mechanism for cell-type specific effects of a given modulator. Receptors are localized to the synaptic neuropil, but are not expressed in the membrane of large diameter processes or the soma. The localization of dopamine receptors in identified pyloric neurons suggests that they may respond to synaptic, paracrine or neurohormonal dopamine signals. This work also supports the idea that different types of signals can be generated by a single receptor. Crustacean GPCR Signal transduction Serotonin cAMP Dopamine Monoamine Stomatogastric Central Pattern Generator Biology, general
147	Heterómeros de receptores de dopamina. Nuevos mecanismos para la regulación de la transmisión dopaminérgica Moreno Guillén, Estefanía 25 April 2012 (has links) El Objetivo General de esta Tesis ha sido investigar la formación y función de heterómeros entre receptores de dopamina y otros receptores que puedan estar implicados en la regulación de la transmisión dopaminérgica, como receptores de galanina, histamina, adrenérgicos o receptores sigma-1. Basándonos en que tanto la galanina como la dopamina modulan la liberación de acetilcolina en el hipocampo, se ha demostrado que los receptores de dopamina de la familia D1 (receptores D1 y D5) pueden formar heterómeros con los receptores de galanina Gal1 y Gal2 y se ha estudiado la función de estos heterómeros en la liberación de acetilcolina en el hipocampo. En el estriado, los receptores de dopamina D1 se localizan en las neuronas GABAérgicas dinorfinérgicas donde también se localizan receptores de histamina H3. Este hecho permite formular la hipótesis de que estos receptores de histamina modulen la transmisión dopaminérgica mediante la formación de heterómeros y que esto pueda explicar algunos de los resultados contradictorios sobre las interacciones funcionales entre receptores H3 y receptores de dopamina. Teniendo en cuenta todo ello, se ha demostrado que los receptores de dopamina D1 pueden formar heterómeros con los receptores de histamina H3 y se han estudiado las implicaciones funcionales de estos heterómeros en cultivos celulares y en el estriado. Las vías dopaminérgicas y especialmente la señalización mediada por los receptores D1 y D2 de dopamina, están profundamente implicadas en la adicción a cocaína. Una gran parte de los efectos mediados por la cocaína se atribuyen a una sobre-estimulación de la señalización de los receptores de dopamina debida al incremento de dopamina ocasionado por la inhibición por cocaína del transportador de dopamina (DAT). Sin embargo, la cocaína, además de interaccionar con DAT, puede unirse a otras proteínas como los receptores sigma-1. En este contexto, es interesante conocer si los receptores sigma 1 pueden modular la funcionalidad de los receptores de dopamina D1 y D2 mediante un proceso de heteromerización. Por ello, se ha demostrado que los receptores D1 y D2 de dopamina pueden formar heterómeros con los receptores sigma-1 e investigado el efecto que ejerce la cocaína, mediado por estos heterómeros, en la transmisión dopaminérgica. El receptor de dopamina D4 pertenece a la familia de receptores de dopamina D2 y, en humanos, es el único que presenta formas polimórficas, las más comunes D4.4, D4.2 y D4.7. Existe una clara relación entre la forma polimórfica D4.7 del receptor D4 humano con el trastorno de hiperactividad y déficit de atención. No existen muchas diferencias funcionales entre las formas polimórficas por lo que no se conoce cuales son las repercusiones bioquímicas de expresar una u otra forma. Nuestra hipótesis de trabajo es que podían existir diferencias en la capacidad de formar heterómeros con otros receptores de dopamina como el D2 y que estos heterómeros podrían modular la liberación de glutamato en el estriado, lo que podría ser relevante en el trastorno de hiperactividad y déficit de atención. Por ello, se ha demostrado que los receptores D2 y D4 de dopamina pueden formar heterómeros en células vivas y en el tejido estriatal y se ha estudiado su papel en la liberación de glutamato en el estriado. Otra particularidad del receptor de dopamina D4 es que es el único receptor dopaminérgico en la glándula pineal de rata sin que se conozca cual es su función a pesar de que se expresa de manera circadiana. Dado que la glándula pineal está bajo el control de los receptores alfa-1B y beta-1 adrenérgicos, cuya activación está altamente relacionada con la regulación del ritmo circadiano y la síntesis y liberación de serotonina y melatonina, una posibilidad es que los receptores de dopamina D4 puedan modular la función de los receptores adrenérgicos de la glándula pineal mediante un proceso de heteromerización. Para estudiar esta posibilidad se ha demostrado que los receptores D4 de dopamina pueden formar heterómeros con los receptores alfa-1B y beta-1 adrenérgicos y se ha investigado su presencia y función en la glándula pineal de rata. / DOPAMINE RECEPTOR´S HETEROMERS. NEW MECHANISMS FOR THE REGULATION OF DOPAMINERGIC TRANSMISSION The main objective of this Thesis has been to investigate the formation and function of heteromers between dopamine and other receptors that might be implicated in the regulation of dopaminergic transmission, such as galanin, histamine, adrenergic or sigma-1 receptors. Firstly, it has been demonstrated that dopamine D1-like family receptors (D1 and D5) can form heteromers with galanin Gal1 and Gal2 receptors. The functional association of these heteromers has been studied within the context of the liberation of acetylcholine in the hippocampus. Secondly, it has been shown that dopamine D1 receptors can form heteromers with histamine H3 receptors. The functional implications of these heteromers have been studied using cellular cultures and native striatum tissue. Thirdly, it has been demonstrated that dopamine D1 and D2 receptors can form heteromers with sigma-1 receptors. The effect of cocaine on the dopaminergic transmission mediated by these heteromers has been investigated. Fourthly, it has been shown that dopamine D2 and D4 receptors can form heteromers both in living cells and striatal tissue and their role on the release of glutamate in the striatum has been studied. Finally, it has been shown that dopamine D4 receptors can form heteromers with adrenergic α1B and β1 receptors, their presence and function has been investigated in rat pineal gland. Heterómeros Dopamina Neurotransmisión Enfermedades neurodegenerativas Ciències Experimentals i Matemàtiques 577
148	Molecular dynamics simulations of seven-transmembrane receptors Cordomí Montoya, Arnau 11 March 2008 (has links) Seven transmembrane (7-TM) G protein coupled receptors (GPCR) constitute the largest family of integral membrane proteins in eukaryotes with more than 1000 members and encoding more than 2% of the human genome. These proteins play a key role in the transmission and transduction of cellular signals responding to hormones, neurotransmitters, light and other agonists, regulating basic biological processes. Their natural abundance together with their localization in the cell membrane makes them suitable targets for therapeutic intervention. Consequently, GPCR are proteins with enormous pharmacologic interest, representing the targets of about 50% of the currently marketed drugs. The current limitations in the experimental techniques necessary for microscopic studies of the membrane as well as membrane proteins emerged the use of computational methods and specifically molecular dynamics simulations. The lead motif of this thesis is the study of GPCR by means of this technique, with the ultimate goal of developing a methodology that can be generalized to the study of most 7-TM as well as other membrane proteins. Since the bovine rhodopsin was the only protein of the GPCR family with a known threedimensional structure at an atomic level until very recently, most of the effort is centered in the study of this receptor as a model of GPCR.The scope of this thesis is twofold. On the one hand it addresses the study of the simulation conditions, including the procedure as well as the sampling box to get optimal results, and on the other, the biological implications of the structural and dynamical behavior observed in the simulations. Specifically, regarding the methodological aspects of the work, the bovine rhodopsin has been studied using different treatments of long-range electrostatic interactions and sampling conditions, as well as the effect of sampling the protein embedded in different one-component lipid bilayers. The binding of ions to lipid bilayers in the absence of the protein has also been investigated. Regarding the biological consequences of the analysis of the MD trajectories, it has been carefully addressed the binding site of retinal and its implications in the process of isomerization after photon uptake, the alteration a group of residues constituting the so-called electrostatic lock between helices TM3 and TM6 in rhodopsin putatively used as common activation mechanism of GPCR, and the structural effects caused by the dimerization based on a recent semi-empirical model. Finally, the specific binding of ions to bacteriorhodopsin has also been studied. The main conclusion of this thesis is provide support to molecular dynamics as technique capable to provide structural and dynamical informational about membranes and membrane proteins, not currently accessible from experimental methods). Moreover, the use of an explicit lipidic environment is crucial for the study the membrane protein dynamics as well as for the protein-protein and lipidprotein interactions. lipid bilayer membrana protein rhoolopsin GPCR molecular dynamics G-protein coupled receptor GROMACS 544 66
149	Physicochemical properties of amino acid sequences of G-proteins for understanding GPCR-G-protein coupling Ghimire, Ganga D., ギミレ, ガンガ　Ｄ, Imai, Kenichiro, 今井, 賢一郎, Akazawa, Fumitsugu, 赤沢, 史嗣, Tsuji, Toshiyuki, 辻, 敏之, Sonoyama, Masashi, 園山, 正史, Mitaku, Shigeki, 美宅, 成樹 January 2006 (has links) (PDF) No description available. GPCR G-protein signal transduction proteomics bioinformatics Gタンパク質シグナル伝達プロテオミクスバイオインフォマティクス
150	Calcium Modulates MGLUR1 Folding in ER in the Trafficking Process and Regulates the Drug Activity Upon the Receptor Expressing on the Cell Membrane Jiang, Yusheng 01 August 2012 (has links) Metabotropic glutamate receptor 1α (mGluR1α) exerts important effects on numerous neurological processes. Although mGluR1α is known to respond to extracellular Ca2+ ([Ca2+]o) and the crystal structures of the extracellular domains (ECDs) of several mGluRs have been determined, the calcium-binding site(s) and structural determinants of Ca2+-modulated signaling in the Glu receptor family remain elusive. Here, we identify a novel Ca2+-binding site (Site 1) in the ECD-mGluR1α using a recently developed computational algorithm. This predicted site (D318, E325, D322 and the bound L-Glu) is situated in the hinge region in the ECD-mGluR1α adjacent to the reported Glu-binding site. Mutagenesis studies indicated that binding of L-Glu and Ca2+ to their distinct but partially overlapping binding sites synergistically modulated mGluR1α activation of intracellular Ca2+ ([Ca2+]i) signaling. Mutating the Glu-binding site completely abolished Glu signaling while leaving its Ca2+-sensing capability largely intact. Mutating the predicted Ca2+-binding residues abolished or significantly reduced the sensitivity of mGluR1α not only to [Ca2+]o and [Gd3+]o but also, in some cases, to Glu. In addition, the Ca2+ effects on drugs targeting mGluR1α were investigated. Ca2+ enhances L-Quis response of the receptor by increasing L-Quis binding to ECD-mGluR1α and promotes the potency of Ro 67-4853, a positive allosteric modulator of mGluR1α. Increasing Ca2+ concentration, the inhibitory effects of a competitive antagonist ((s)-MCPG) and a non-competitive negative allosteric modulator (CPCCOEt), were eliminated. Furthermore, we also identified another potential Ca2+ binding pocket (Site 2) consists of S165, D208, Y236 and D318, which completely overlapped with L-Glu. Thapsigargin (TG) induced ER Ca2+ depletion reduced surface expression of mGluR1α, and D208I and Y236I also decreased the receptor trafficking to plasma membrane suggesting the role of Ca2+ binding in protein folding and trafficking in the ER. Further, to measure ER Ca2+, a series of genetically encoded biosensors were designed by placing a Ca2+ binding pocket at the chromophore sensitive region of red florescent protein mCherry. The designed sensors are able to bind Ca2+ and monitor Ca2+ concentration change both in vitro and in cells. The findings in this dissertation open up new avenues for developing allosteric modulators of mGluR function that target related human diseases. Metabotropic glutamate receptor 1 GPCR Calcium Drug Trafficking Folding MCherry Calcium sensor

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