29 research outputs found

    Spatial intensity distribution analysis: studies of G Protein-coupled receptor oligomerization

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    Spatial intensity distribution analysis (SpIDA) is a recently developed approach for determining quaternary structure information on fluorophore-labelled proteins of interest in situ. It can be applied to live or fixed cells and native tissue. Using confocal images, SpIDA generates fluorescence intensity histograms that are analysed by super-Poissonian distribution functions to obtain density and quantal brightness values of the fluorophore-labelled protein of interest. This allows both expression level and oligomerisation state of the protein to be determined. We describe the application of SpIDA to investigate the oligomeric state of G protein-coupled receptors (GPCRs) at steady state and following cellular challenge, and consider how SpIDA may be used to explore GPCR quaternary organisation in pathophysiology and to stratify medicines

    Ligand regulation of the quaternary organization of cell surface M3 muscarinic acetylcholine receptors analyzed by fluorescence resonance energy transfer (FRET) imaging and homogenous time-resolved FRET

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    Flp-In T-REx 293 cells expressing a wild type human M muscarinic acetylcholine receptor construct constitutively and able to express a Receptor Activated Solely by Synthetic Ligand (RASSL) form of this receptor on demand maintained response to the muscarinic agonist carbachol but developed response to clozapine-N-oxide only upon induction of the RASSL. The two constructs co-localized at the plasma membrane and generated strong ratiometric fluorescence resonance energy transfer (FRET) signals consistent with direct physical interactions. Increasing levels of induction of the FRET-donor RASSL did not alter wild type receptor FRET-acceptor levels substantially. However, ratiometric FRET was modulated in a bell-shaped fashion with maximal levels of the donor resulting in decreased FRET. Carbachol, but not the antagonist atropine, significantly reduced the FRET signal. Cell surface homogenous time-resolved FRET, based on SNAP-tag technology and employing wild type and RASSL forms of the human M receptor expressed stably in Flp-In TREx 293 cells, also identified cell surface dimeric/oligomeric complexes. Now, however, signals were enhanced by appropriate selective agonists. At the wild type receptor large increases in FRET signal to carbachol and acetylcholine were concentration-dependent with EC values consistent with the relative affinities of the two ligands. These studies confirm the capacity of the human M muscarinic acetylcholine receptor to exist as dimeric/oligomeric complexes at the surface of cells and demonstrate that the organization of such complexes can be modified by ligand binding. However, conclusions as to the effect of ligands on such complexes may depend on the approach used

    Sodium Dependent Mechanisms Regulating Membrane Potassium (86Rb+) Permeability in Mammalian Exocrine Glands In Vitro

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    Fragments of rat submandibular gland were pre-loaded with 86Rb+, a radioactive isotopic marker of cellular K+ permeability, and rate constants for 86Rb+-efflux were determined during superfusion with unlabelled experimental physiological saline solutions which were buffered with either CO2/HCO3- or HEPES/NaOH. Initial 86Rb+-efflux experiments demonstrated that in the presence of external Na+ ([Na+]0), acetylcholine (ACh) could evoke a rapid increase in membrane K+ permeability. This increase could be resolved into two separate components, a Ca2+-independent transient phase which was attributed to the mobilisation of Ca2+ from internal stores and a Ca2+-dependent sustained phase which was evoked when extracellular Ca2+ ([Ca2+]0) was transported into the rat submandibular acini. This biphasic response to ACh was slightly impaired under HCO3-free conditions. It has been suggested that receptor-regulated Ca2+-influx in exocrine organs occurs via a Na+-dependent mechanism (Gallacher & Morris,1987), so the effects of removing external Na+ ([Na+]0) upon this biphasic increase in membrane K+ permeability was investigated. The impermeant cation N-Methyl-D-Glucammonium (NMDG+) or the permeant cation lithium (Li+) were used as Na+ substituents. It was found that the sustained response to ACh was significantly inhibited. These findings therefore supported Gallacher & Morris's (1987) hypothesis that Ca2+-inflow, which supports the sustained increase in the K+ efflux rate from rodent salivary acini, occurs via a Na+-dependent process (Gallacher & Morris, 1987). Although the data from the Na+-free experiments supported Gallacher and Morris's hypothesis, the data from these experiments also suggested that NMDG+ may exert an inhibitory effect on the transient response (Ca2+ mobilisation). This slight inhibition could be a direct effect of NMDG+ or could be due to the initially very low Ca2+ (0.02 mumol 1-1) composition of these HEPES-buffered, NMDG+-solutions since the salivary fragments would have been exposed to an outwardly directed Ca2+ gradient. The effects of NMDG+ upon membrane K+ permeability in the rat submandibular gland were therefore re-examined using HCO3-buffered, NMDG+-solutions in which the [Ca2+]0 was never lower than 0.2 mumol 1-1. The results from these experiments demonstrated that both components of the response to ACh were significantly inhibited in the presence of NMDG+. These latter findings, therefore do not support the view of Gallacher & Morris (1987) that only Ca2+-inflow into rodent submandibular acini is inhibited in the absence of [Na+]o. Furthermore, these findings contrast with analogous NMDG+-experiments undertaken in the human sweat gland where only Ca2+ mobilisation appears to he Na+ dependent (Wilson, Bovell, Elder, Jenkinson & Pediani, 1990). The physiological basis for this dependence upon [Na+]0 is not yet known. However, one hypothesis is that if proton (H+) extrusion via the Na+-H+ exchanger is blocked in the presence of NMDG+, then the resultant fall in intracellular pH (pHi) could inhibit the mobilisation of Ca2+ from internal and external pools (Grinstein & Goetz, 1985; Siffert & Akkerman, 1987; Gallacher & Morris, 1987). It is thus possible that the inhibitory effects evoked by NMDG+ in the rat submandibular gland and human sweat gland may also be due to inhibition of this transport system. This possibility was therefore investigated by examining the degree to which amiloride, a potent inhibitor of Na+-H+ exchange, could impair the cholinergic regulation of membrane K+ permeability in the rat submandibular gland and the human sweat gland. Amiloride (1 mmol 1-1) did not affect membrane K+ permeability in the rat submandibular gland, but this compound did, however, impair the regulation of membrane K+ permeability in the human sweat gland. These data suggested that the ACh-evoked K+ permeability coupling process in the human sweat gland is more sensitive to a fall in pHi. Another thesis put forward to explain this Na+-dependency is that the transport of [Ca2+]0 into rodent submandibular acini occurs via 'reversed' Na+-Ca2+ exchange i.e. [Na+]i exchanged for [Ca2+], (Gallacher & Morris, 1987). I therefore used 45Ca2+ to monitor the transport of Ca2+ in the rat submandibular gland. The data from these experiments demonstrated that the basal 45Ca2+ efflux rate was unaffected when either Na+ or Ca2+ was removed from the superfusing control solution. These results therefore suggest that Na+-Ca2+ exchange does not play an important role in maintaining low internal Ca2+ in this tissue and it is therefore very unlikely that Ca2+-influx occurs via 'reversed' Na+-Ca2+ exchange. (Abstract shortened by ProQuest.)

    Dynamic regulation of quaternary organization of the M1 muscarinic receptor by subtype-selective antagonist drugs

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    Although rhodopsin-like G protein-coupled receptors can exist as both monomers and non-covalently associated dimers/oligomers, the steady-state proportion of each form and whether this is regulated by receptor ligands is unknown. Herein we address these topics for the M1 muscarinic acetylcholine receptor, a key molecular target for novel cognition enhancers, by employing Spatial Intensity Distribution Analysis. This method can measure fluorescent particle concentration and assess oligomerization states of proteins within defined regions of living cells. Imaging and analysis of the basolateral surface of cells expressing some 50 molecules.microm-2 of the human muscarinic M1 receptor identified an ~75/25 mixture of receptor monomers and dimers/oligomers. Both sustained and shorter-term treatment with the selective M1 antagonist pirenzepine resulted in a large shift in the distribution of receptor species to favor the dimeric/oligomeric state. Although sustained treatment with pirenzepine also resulted in marked upregulation of the receptor, simple mass-action effects were not the basis for ligand-induced stabilization of receptor dimers/oligomers. The related antagonist telenzepine also produced stabilization and enrichment of the M1 receptor dimer population but the receptor subtype non-selective antagonists atropine and N-methylscopolamine did not. In contrast, neither pirenzepine nor telenzepine altered the quaternary organization of the related M3 muscarinic receptor. These data provide unique insights into the selective capacity of receptor ligands to promote and/or stabilize receptor dimers/oligomers and demonstrate that the dynamics of ligand regulation of the quaternary organization of G protein-coupled receptors is markedly more complex than previously appreciated. This may have major implications for receptor function and behavior

    Spatial intensity distribution analysis quantifies the extent and regulation of homodimerization of the secretin receptor

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    Previous studies have indicated that the G protein-coupled secretin receptor is present as a homo-dimer, organized through symmetrical contacts in transmembrane domain IV, and that receptor dimerization is critical for high potency signalling by secretin. However, whether all of the receptor exists in the dimeric form or if this is regulated, is unclear. We used measures of quantal brightness of the secretin receptor tagged with monomeric enhanced green fluorescent protein (mEGFP) and Spatial Intensity Distribution Analysis to assess this. Calibration using cells expressing plasma membrane-anchored forms of mEGFP initially allowed demonstration that the Epidermal Growth Factor receptor is predominantly monomeric in the absence of ligand and whilst wild type receptor was rapidly converted to a dimeric form by ligand, a mutated form of this receptor remained monomeric. Equivalent studies showed that at moderate expression levels the secretin receptor exists as a mixture of monomeric and dimeric forms, with little evidence of higher-order complexity. However, sodium butyrate induced up-regulation of the receptor resulted in a shift from monomeric towards oligomeric organization. By contrast, a form of the secretin receptor containing a pair of mutations on the lipid-facing side of transmembrane domain IV was almost entirely monomeric. Down-regulation of the secretin receptor-interacting G protein Gαs did not alter receptor organization, indicating that dimerization is defined specifically by direct protein-protein interactions between copies of the receptor polypeptide, whilst short term treatment with secretin had no effect on organization of the wild type receptor but increased the dimeric proportion of the mutated receptor variant

    A molecular basis for selective antagonist destabilization of dopamine D3 receptor quaternary organization

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    The dopamine D3 receptor (D3R) is a molecular target for both first-generation and several recently-developed antipsychotic agents. Following stable expression of this mEGFP-tagged receptor, Spatial Intensity Distribution Analysis indicated that a substantial proportion of the receptor was present within dimeric/oligomeric complexes and that increased expression levels of the receptor favored a greater dimer to monomer ratio. Addition of the antipsychotics, spiperone or haloperidol, resulted in re-organization of D3R quaternary structure to promote monomerization. This action was dependent on ligand concentration and reversed upon drug washout. By contrast, a number of other antagonists with high affinity at the D3R, did not alter the dimer/monomer ratio. Molecular dynamics simulations following docking of each of the ligands into a model of the D3R derived from the available atomic level structure, and comparisons to the receptor in the absence of ligand, were undertaken. They showed that, in contrast to the other antagonists, spiperone and haloperidol respectively increased the atomic distance between reference α carbon atoms of transmembrane domains IV and V and I and II, both of which provide key interfaces for D3R dimerization. These results offer a molecular explanation for the distinctive ability of spiperone and haloperidol to disrupt D3R dimerization

    Multiple AMPK activators inhibit L-Carnitine uptake in C2C12 skeletal muscle myotubes

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    Mutations in the gene that encodes the principal L-Carnitine transporter, OCTN2, can lead to a reduced intracellular L-Carnitine pool and the disease Primary Carnitine Deficiency. L-Carnitine supplementation is used therapeutically to increase intracellular L-Carnitine. As AMPK and insulin regulate fat metabolism and substrate uptake we hypothesised that AMPK activating compounds and insulin would increase L-Carnitine uptake in C2C12myotubes. The cells express all three OCTN transporters at the mRNA level and immunohistochemistry confirmed expression at the protein level. Contrary to our hypothesis, despite significant activation of PKB and 2DG uptake, insulin did not increase L-Carnitine uptake at 100nM. However, L-Carnitine uptake was modestly increased at a dose of 150nM insulin. A range of AMPK activators that increase intracellular calcium content [caffeine (10mM, 5mM, 1mM, 0.5mM), A23187 (10μM)], inhibit mitochondrial function [Sodium Azide (75μM), Rotenone (1μM), Berberine (100μM), DNP (500μM)] or directly activate AMPK [AICAR (250μM)] were assessed for their ability to regulate L-Carnitine uptake. All compounds tested significantly inhibited L-Carnitine uptake. Inhibition by caffeine was not dantrolene (10μM) sensitive. Saturation curve analysis suggested that caffeine did not competitively inhibit L-Carnitine transport. However, the AMPK inhibitor Compound C (10μM) partially rescued the effect of caffeine suggesting that AMPK may play a role in the inhibitory effects of caffeine. However, caffeine likely inhibits L-Carnitine uptake by alternative mechanisms independently of calcium release. PKA activation or direct interference with transporter function may play a role

    A general method to quantify ligand-driven oligomerization from fluorescence-based images

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    Here, we introduce fluorescence intensity fluctuation spectrometry for determining the identity, abundance and stability of protein oligomers. This approach was tested on monomers and oligomers of known sizes and was used to uncover the oligomeric states of the epidermal growth factor receptor and the secretin receptor in the presence and absence of their agonist ligands. This method is fast and is scalable for high-throughput screening of drugs targeting protein–protein interactions

    The protein kinase C inhibitor, Ro-31-7459, is a potent activator of ERK and JNK MAP kinases in HUVECs and yet inhibits cyclic AMP-stimulated <i>SOCS-3</i> gene induction through inactivation of the transcription factor c-Jun

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    Induction of the suppressor of cytokine signalling 3 (SOCS-3) gene is vital to the normal control of inflammatory signalling. In order to understand these processes we investigated the role of the proto-oncogene component of the AP-1 transcription factor complex, c-Jun, in the regulation of SOCS-3 gene induction. We found that cyclic AMP stimulation of HUVECs promoted phosphorylation and activation of JNK MAP kinase and its substrate c-Jun. The JNK responsive element of the human SOCS-3 promoter mapped to a putative AP-1 site within 1000 bp of the transcription start site. The PKC inhibitors, GF-109203X, Gö-6983 and Ro-317549, were all found to inhibit AP-1 transcriptional activity, transcriptional activation of this minimal SOCS-3 promoter and SOCS-3 gene induction in HUVECs. Interestingly, Ro-317549 treatment was also found to promote PKC-dependent activation of ERK and JNK MAP kinases and promote JNK-dependent hyper-phosphorylation of c-Jun, whereas GF-109203X and Gö-6983 had little effect. Despite this, all three PKC inhibitors were found to be effective inhibitors of c-Jun DNA-binding activity. The JNK-dependent hyper-phosphorylation of c-Jun in response to Ro-317549 treatment of HUVECs does therefore not interfere with its ability to inhibit c-Jun activity and acts as an effective inhibitor of c-Jun-dependent SOCS-3 gene induction

    Differences in the signaling pathways of α1A- and α1B-adrenoceptors are related to different endosomal targeting

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    Aims: To compare the constitutive and agonist-dependent endosomal trafficking of α1A- and α1B-adrenoceptors (ARs) and to establish if the internalization pattern determines the signaling pathways of each subtype. Methods: Using CypHer5 technology and VSV-G epitope tagged α1A- and α1B-ARs stably and transiently expressed in HEK 293 cells, we analyzed by confocal microscopy the constitutive and agonist-induced internalization of each subtype, and the temporal relationship between agonist induced internalization and the increase in intracellular calcium (determined by FLUO-3 flouorescence), or the phosphorylation of ERK1/2 and p38 MAP kinases (determined by Western blot). Results and Conclusions: Constitutive as well as agonist-induced trafficking of α1A and α1B ARs maintain two different endosomal pools of receptors: one located close to the plasma membrane and the other deeper into the cytosol. Each subtype exhibited specific characteristics of internalization and distribution between these pools that determines their signaling pathways: α1A-ARs, when located in the plasma membrane, signal through calcium and ERK1/2 pathways but, when translocated to deeper endosomes, through a mechanism sensitive to β-arrestin and concanavalin A, continue signaling through ERK1/2 and also activate the p38 pathway. α1B-ARs signal through calcium and ERK1/2 only when located in the membrane and the signals disappear after endocytosis and by disruption of the membrane lipid rafts by methyl-β-cyclodextrin
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