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Nature and Function of the Signaling Complex Formed by the M2 Muscarinic Cholinergic ReceptorMa, Amy Wing-Shan 05 December 2012 (has links)
G protein-coupled receptors (GPCRs) are known to exist as oligomers, but there is much uncertainty over the oligomeric size, the number of interacting G proteins and the stability of that interaction. The present approach to these questions has been threefold. Monomers of the M2 muscarinic receptor were purified from Spodoptera frugiperda (Sf9) cells and reconstituted in phospholipid vesicles, where they spontaneously formed tetramers. The size of the reconstituted complex was determined from its electrophoretic mobility after cross-linking and inferred from a quantitative, model-based assessment of cooperative effects in the binding of two muscarinic antagonists: N-methylscopolamine and quinuclidinylbenzilate. Binding of the agonist oxotremorine-M to receptor reconstituted with purified G proteins revealed at least three classes of sites that interconverted from higher to lower affinity upon the addition of guanylylimidotriphosphate (GMP-PNP). The binding properties resemble those of muscarinic receptors in myocardial preparations, thereby implying the existence of tetramers in native tissues. G proteins that copurify with the M2 receptor from cardiac membranes also were found to exist as oligomers, some of which contain both alpha(o) and alpha(i2), and the purified complexes contained receptor and G protein in near-equal amounts. A tetrameric receptor implies a tetramer of G proteins, a conclusion that is supported by the distribution of sites between different states identified in the binding of [35S]GTPgammaS to the purified complex. Covalent adducts of a GPCR fused to a Galpha-subunit provide a model system in which the relationship between receptor and G protein complex is defined with respect to stability and composition. Such a fusion of the M2 receptor and Galpha(i1) underwent a cleavage near the amino terminus of the alpha-subunit, however, flagging the likelihood of similar effects in other such adducts. Truncation of the amino terminus prior to fusion generated a stable product that revealed GMP-PNP-sensitive, biphasic binding of oxotremorine-M and noncompetitive interactions between N-methylscopolamine and quinuclidinylbenzilate. A covalent RG complex therefore exhibits the functional properties of M2 receptors in native systems. These observations are consistent with the notion that signaling through the M2 receptor occurs via cooperative interactions within a stable complex that comprises four receptors and four G proteins.
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Nature and Function of the Signaling Complex Formed by the M2 Muscarinic Cholinergic ReceptorMa, Amy Wing-Shan 05 December 2012 (has links)
G protein-coupled receptors (GPCRs) are known to exist as oligomers, but there is much uncertainty over the oligomeric size, the number of interacting G proteins and the stability of that interaction. The present approach to these questions has been threefold. Monomers of the M2 muscarinic receptor were purified from Spodoptera frugiperda (Sf9) cells and reconstituted in phospholipid vesicles, where they spontaneously formed tetramers. The size of the reconstituted complex was determined from its electrophoretic mobility after cross-linking and inferred from a quantitative, model-based assessment of cooperative effects in the binding of two muscarinic antagonists: N-methylscopolamine and quinuclidinylbenzilate. Binding of the agonist oxotremorine-M to receptor reconstituted with purified G proteins revealed at least three classes of sites that interconverted from higher to lower affinity upon the addition of guanylylimidotriphosphate (GMP-PNP). The binding properties resemble those of muscarinic receptors in myocardial preparations, thereby implying the existence of tetramers in native tissues. G proteins that copurify with the M2 receptor from cardiac membranes also were found to exist as oligomers, some of which contain both alpha(o) and alpha(i2), and the purified complexes contained receptor and G protein in near-equal amounts. A tetrameric receptor implies a tetramer of G proteins, a conclusion that is supported by the distribution of sites between different states identified in the binding of [35S]GTPgammaS to the purified complex. Covalent adducts of a GPCR fused to a Galpha-subunit provide a model system in which the relationship between receptor and G protein complex is defined with respect to stability and composition. Such a fusion of the M2 receptor and Galpha(i1) underwent a cleavage near the amino terminus of the alpha-subunit, however, flagging the likelihood of similar effects in other such adducts. Truncation of the amino terminus prior to fusion generated a stable product that revealed GMP-PNP-sensitive, biphasic binding of oxotremorine-M and noncompetitive interactions between N-methylscopolamine and quinuclidinylbenzilate. A covalent RG complex therefore exhibits the functional properties of M2 receptors in native systems. These observations are consistent with the notion that signaling through the M2 receptor occurs via cooperative interactions within a stable complex that comprises four receptors and four G proteins.
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Mechanism of G Protein Beta-Gamma Assembly Mediated by Phosducin-Like Protein 1Lai, Chun Wan Jeffrey 15 December 2011 (has links) (PDF)
G-protein coupled receptor signaling (GPCR) is essential for regulating a large variety of hormonal, sensory and neuronal processes in eukaryotic cells. Because the regulation of these physiological responses is critical, GPCR signaling pathways are carefully controlled at different levels within the cascade. Phosducin-like protein 1 (PhLP1) can bind the G protein βγ dimer and participate in GPCR signaling. Recent evidence has supported the concept that PhLP1 can serve as a co-chaperone of the eukaryotic cytosolic chaperonin complex CCT/TRiC to mediate G βγ assembly. Although a general mechanism of PhLP1-mediated G βγ assembly has been postulated, many of the details about this process are still missing. Structural analysis of key complexes that are important intermediates in the G βγ assembly process can generate snapshots that provide molecular details of the mechanism beyond current understanding. We have isolated two important intermediates in the assembly process, the Gβ1-CCT and PhLP1-Gβ1-CCT complexes assembled in vivo in insect cells, and have determined their structures by cryo-electron microscopy (cryo-EM). Structural analysis reveals that Gβ1, representing the WD40 repeat proteins which are a major class of CCT substrates, interacts specifically with the apical domain of CCTβ. Gβ1 binding experiments with several chimeric CCT subunits confirm a strong interaction of Gβ1 with CCTβ and map Gβ1 binding to α-Helix 9 and the loop between β-strands 6 and 7. These regions are part of a hydrophobic surface of the CCTβ apical domain facing the chaperonin cavity. Docking the Gβ molecule into the two 3D reconstructions (Gβ1-CCT and PhLP1-Gβ1-CCT) reveals that upon PhLP1 binding to Gβ1-CCT, the quasi-folded Gβ molecule is constricted to a more native state and shifted to an angle that can lead to the release of folded Gβ1 from CCT. Moreover, mutagenesis of the CCTβ subunit suggests that PhLP1 can interact with the tip of the apical domain of CCTβ subunit at residue S260, which is a downstream phosphorylation target site of RSK and S6K kinases from the Ras-MAPK and mTOR pathways. These results reveal a novel mechanism of PhLP1-mediated Gβ folding and its release from CCT. The next important step in testing the PhLP1-mediated Gβγ assembly hypothesis is to investigate the function of PhLP1 in vivo. We have prepared a rod-specific PhLP1 conditional knockout mouse in which the physiological consequences of the loss of PhLP1 functions have been characterized. The loss of PhLP1 has led to profound consequences on the ability of these rods to detect light as a result of a significant reduction in the expression of transducin (Gt) subunits. Expression of other G protein subunits as well as Gβ5-RGS9-1 complexes was also greatly decreased, yet all of this occurs without resulting in rapid degeneration of the photoreceptor cells. These results show for the first time the essential nature of PhLP1 for Gβγ and Gβ5-RGS dimer assembly in vivo, confirming results from cell culture and structural studies.
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Gβγ acts at an inter-subunit cleft to activate GIRK1 channelsMahajan, Rahul 09 October 2012 (has links)
Heterotrimeric guanine nucleotide-binding proteins (G-proteins) consist of an alpha subunit (Gα) and the dimeric beta-gamma subunit (Gβγ). The first example of direct cell signaling by Gβγ was the discovery of its role in activating G-protein regulated inwardly rectifying K+ (GIRK) channels which underlie the acetylcholine-induced K+ current responsible for vagal inhibition of heart rate. Published crystal structures have provided important insights into the structures of the G-protein subunits and GIRK channels separately, but co-crystals of the channel and Gβγ together remain elusive and no specific reciprocal residue interactions between the two proteins are currently known. Given the absence of direct structural evidence, we attempted to identify these functionally important channel-Gβγ interactions using a computational approach. We developed a multistage computational docking algorithm that combines several known methods in protein-protein docking. Application of the docking protocol to previously published structures of Gβγ and GIRK1 homomeric channels produced a clear signal of a favored binding mode. Analysis of this binding mode suggested a mechanism by which Gβγ promotes the open state of the channel. The channel-Gβγ interactions predicted by the model in silico could be disrupted in vitro by mutation of one protein and rescued by additional mutation of reciprocal residues in the other protein. These interactions were found to extend to agonist induced activation of the channels as well as to activation of the native heteromeric channels. Currently, the structural mechanism by which Gβγ regulates the functional conformations of GIRK channels or of any of its membrane-associated effector proteins is not known. This work shows the first evidence for specific reciprocal interactions between Gβγ and a GIRK channel and places these interactions in the context of a general model of intracellular regulation of GIRK gating.
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Regulation der Aktivität der vesikulären Monoamintransporter VMAT1 und VMAT2 in neuroendokrinen Zellen und NeuronenHöltje, Markus 12 September 2000 (has links)
In der vorliegenden Arbeit wurde die Regulation der Aktivität der vesikulären Monoamintransporter VMAT1 und VMAT2 durch heterotrimere G-Proteine untersucht. In der humanen neuroendokrinen Zellinie BON werden VMAT1 und VMAT2 exprimiert. Sie colokalisieren in diesen Zellen mit der a-Untereinheit des heterotrimeren G-Proteins Go2 vorwiegend auf großen elektronendichten Vesikeln, den LDCVs. Die Aktivität beider Transporter unterliegt einer Regulation durch Gao2. Nach Aktivierung des G-Proteins kommt es zu einer Hemmung der vesikulären Monoaminaufnahme. Die Aktivität von VMAT2 wird dabei empfindlicher reguliert als die Aktivität von VMAT1. In Primärkulturen von Rapheneuronen der Ratte wird VMAT2 als neuronale Variante des Transporters exprimiert. VMAT2 lokalisiert in diesen Neuronen überwiegend auf kleinen synaptischen Vesikeln, den SSVs. Hier kommt es zu einer Colokalisation mit Gao2 auf diesem Vesikeltyp. Auch in Rapheneuronen wird die Aktivität von VMAT2 durch diese G-Protein Untereinheit gehemmt. Elektronenmikroskopische Befunde belegen die Lokalisation von VMAT2 und Gao2 auf SSVs von serotonergen Axonterminalen im präfrontalen Cortex der Ratte. An einer Präparation synaptischer Vesikel aus diesem Gehirnbereich konnte ebenfalls eine Hemmung der Transportaktivität von VMAT2 durch Gao2 nachgewiesen werden. Auch in Thrombozyten der Maus unterliegt die vesikuläre Serotoninaufnahme einer Hemmung durch ein heterotrimeres G-Protein. In chronisch entleerten Vesikeln aus Mäusen, in denen das Gen für die periphere Tryptophanhydroxylase deletionsmutiert vorlag, konnte zunächst keine Hemmung der Serotoninaufnahme durch heterotrimere G-Proteine beobachtet werden. Nach Vorbeladung der Vesikel mit Serotonin war dies jedoch der Fall. Die Aktivierung des G-Proteins wird somit sehr wahrscheinlich über den Füllungszustand der Vesikel gesteuert. / In this study we investigated the regulation of the activity of the vesicular monoamine transporters VMAT1 and VMAT2 by heterotrimeric G-proteins. In the human neuroendocrine cell line BON both transporters are expressed. They colocalize in these cells with the a-subunit of the heterotrimeric G-protein Go2 predominantely on Large Dense Core Vesicles (LDCVs). The activity of both VMAT1 and VMAT2 is regulated by Gao2. G-protein activation results in a down-regulation of vesicular monoamine uptake. VMAT2 appears to be more sensitive towards the observed G-protein regulation than VMAT1. Serotonergic raphe neurons in primary culture express VMAT2 as the neuronal form of the transporter. In these neurons VMAT2 predominantely localizes to Small Synaptic Vesicles (SSVs). Here, VMAT2 colocalizes with Gao2 on SSVs. In these neurons Gao2-dependent down-regulation of VMAT2 activity was observed, too. Immunoelectron microscopic analysis confirmed a localization of VMAT2 and Gao2 on SSVs from serotonergic terminals in the rat prefrontal cortex. In addition, Gao2-dependent regulation of VMAT2 activity could also be demonstrated when using a crude synaptic vesicle preparation of this brain area. Even in platelets obtained from mice the vesicular serotonin uptake is down-regulated by heterotrimeric G-proteins. In serotonin-depleted platelets from peripheral tryptophane-hydroxylase knockout mice no G-protein-dependent down-regulation of monoamine uptake was observed. After preincubation of the platelets with serotonin, the G-protein regulation was restored. Therefore, the vesicular transmitter content appears to be a likely factor of G-protein activation in platelets.
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Role of the Heterotrimeric Go Protein Alpha-subunit on the Cardiac Secretory PhenotypeRoeske, Cassandra 21 May 2013 (has links)
Atrial natriuretic factor (ANF) is a polypeptide hormone produced in heart atria, stored in atrial secretory granules and released into the circulation in response to various stimuli. Proper sorting of ANF at the level of the trans-Golgi network (TGN) is required for the storage of ANF in these specific granules, and this sorting of hormones has been found to be associated with G-proteins. Specifically, the Go protein alpha-subunit (Gαo) was established to participate in the stretch-secretion coupling of ANF, but may also be involved in the transporting of ANF from the TGN into atrial granules for storage and maturation. Based on knowledge of Gαo involvement in hormone production in other endocrine tissues, protein-protein interactions of Gαo and proANF and their immunochemical co-localization in granules, the direct involvement of these two proteins in atrial granule biogenesis is probable. In this study, mice were created using the Cre/lox recombination system with a conditional Gαo knockout in cardiocytes to study and characterize ANF production, secretion and granule formation. Deletion of this gene was successful following standard breeding protocols. Characterization and validation of cellular and molecular content of the knockout mice through mRNA levels, protein expression, peptide content, electron microscopy, and electrocardiography determined that a significant phenotypic difference was observed in the abundance of atrial granules. However, Gαo knockout mice did not significantly alter the production and secretion of ANF and only partially prevented granule biogenesis, likely due to incomplete Gαo knockout. These studies demonstrate an involvement of Gαo in specific atrial granule formation.
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Role of the Heterotrimeric Go Protein Alpha-subunit on the Cardiac Secretory PhenotypeRoeske, Cassandra January 2013 (has links)
Atrial natriuretic factor (ANF) is a polypeptide hormone produced in heart atria, stored in atrial secretory granules and released into the circulation in response to various stimuli. Proper sorting of ANF at the level of the trans-Golgi network (TGN) is required for the storage of ANF in these specific granules, and this sorting of hormones has been found to be associated with G-proteins. Specifically, the Go protein alpha-subunit (Gαo) was established to participate in the stretch-secretion coupling of ANF, but may also be involved in the transporting of ANF from the TGN into atrial granules for storage and maturation. Based on knowledge of Gαo involvement in hormone production in other endocrine tissues, protein-protein interactions of Gαo and proANF and their immunochemical co-localization in granules, the direct involvement of these two proteins in atrial granule biogenesis is probable. In this study, mice were created using the Cre/lox recombination system with a conditional Gαo knockout in cardiocytes to study and characterize ANF production, secretion and granule formation. Deletion of this gene was successful following standard breeding protocols. Characterization and validation of cellular and molecular content of the knockout mice through mRNA levels, protein expression, peptide content, electron microscopy, and electrocardiography determined that a significant phenotypic difference was observed in the abundance of atrial granules. However, Gαo knockout mice did not significantly alter the production and secretion of ANF and only partially prevented granule biogenesis, likely due to incomplete Gαo knockout. These studies demonstrate an involvement of Gαo in specific atrial granule formation.
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