Emmanuel Bourrier scite author profile

Cell-surface proteins are important in cell-cell communication. They assemble into heterocomplexes that include different receptors and effectors. Elucidation and manipulation of such protein complexes offers new therapeutic possibilities. We describe a methodology combining time-resolved fluorescence resonance energy transfer (FRET) with snap-tag technology to quantitatively analyze protein-protein interactions at the surface of living cells, in a high throughput-compatible format. Using this approach, we examined whether G protein-coupled receptors (GPCRs) are monomers or assemble into dimers or larger oligomers--a matter of intense debate. We obtained evidence for the oligomeric state of both class A and class C GPCRs. We also observed different quaternary structure of GPCRs for the neurotransmitters glutamate and gamma-aminobutyric acid (GABA): whereas metabotropic glutamate receptors assembled into strict dimers, the GABA(B) receptors spontaneously formed dimers of heterodimers, offering a way to modulate G-protein coupling efficacy. This approach will be useful in systematic analysis of cell-surface protein interaction in living cells.

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Time-resolved FRET between GPCR ligands reveals oligomers in native tissues

Albizu

et al. 2010

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G protein–coupled receptor (GPCR) oligomers have been proposed to play critical roles in cell signaling, but confirmation of their existence in a native context remains elusive, as no direct interactions between receptors have been reported. To demonstrate their presence in native tissues, we developed a time-resolved FRET strategy that is based on receptor labeling with selective fluorescent ligands. Specific FRET signals were observed with four different receptors expressed in cell lines, consistent with their dimeric or oligomeric nature in these transfected cells. More notably, the comparison between FRET signals measured with sets of fluorescent agonists and antagonists was consistent with an asymmetric relationship of the two protomers in an activated GPCR dimer. Finally, we applied the strategy to native tissues and succeeded in demonstrating the presence of oxytocin receptor dimers and/or oligomers in mammary gland.

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Rapid sensing of circulating ghrelin by hypothalamic appetite-modifying neurons

Schaeffer

Langlet

Lafont

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

268

198

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To maintain homeostasis, hypothalamic neurons in the arcuate nucleus must dynamically sense and integrate a multitude of peripheral signals. Blood-borne molecules must therefore be able to circumvent the tightly sealed vasculature of the blood-brain barrier to rapidly access their target neurons. However, how information encoded by circulating appetite-modifying hormones is conveyed to central hypothalamic neurons remains largely unexplored. Using in vivo multiphoton microscopy together with fluorescently labeled ligands, we demonstrate that circulating ghrelin, a versatile regulator of energy expenditure and feeding behavior, rapidly binds neurons in the vicinity of fenestrated capillaries, and that the number of labeled cell bodies varies with feeding status. Thus, by virtue of its vascular connections, the hypothalamus is able to directly sense peripheral signals, modifying energy status accordingly.hormone diffusion | in vivo imaging | median eminence | metabolism C ontinuous integration of peripheral signals by neurons belonging to the arcuate nucleus of the hypothalamus (ARH) is critical for central regulation of energy balance and neuroendocrine function (1). To dynamically report alterations to homeostasis and ensure an appropriate neuronal response, blood-borne factors such as hormones must rapidly access the central nervous system (CNS). This is particularly evident in the case of food intake, which is regulated by a plethora of circulating satiety signals (2) whose levels fluctuate in an ultradian manner. Despite this, it remains unclear how key energy status-signaling hormones such as ghrelin can be rapidly sensed by target neurons to alter feeding responses (3). Elucidation of the mechanisms underlying molecule entry into the brain is important for understanding not only normal maintenance of homeostasis but also how this is perturbed during common pathologies such as obesity and diabetes (4, 5).Although molecule transport mechanisms within the ARH are poorly characterized, they likely assume one of two forms. First, chronic feedback may be accomplished by uptake of circulating molecules into the ARH via saturable receptor-mediated transport at the level of the choroid plexus and/or bloodbrain barrier (BBB) (6-9). Second, the ARH is morphologically located in close apposition to the median eminence (ME), a circumventricular organ composed of fenestrated capillaries. Because these vessels project toward the ventromedial ARH (vmARH), they could represent a direct vascular input for passive diffusion of peripheral molecules into the hypothalamus (10-13). So far, study of the functional importance of fenestrated capillaries in molecule entry into the metabolic brain has been impeded by lack of appropriate tools.To evaluate the role of fenestrated ME/ARH capillaries in rapid detection of peripheral signals by the hypothalamus, we used a recently developed in vivo imaging approach to visualize in real time the extravasation of fluorescent molecules (14). Ghrelin was chosen as a candidate hormone because i...

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A Fluorescent Ligand-Binding Alternative Using Tag-lite® Technology

et al. 2010

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G-protein-coupled receptors (GPCRs) are crucial cell surface receptors that transmit signals from a wide range of extracellular ligands. Indeed, 40% to 50% of all marketed drugs are thought to modulate GPCR activity, making them the major class of targets in the drug discovery process. Binding assays are widely used to identify high-affinity, selective, and potent GPCR drugs. In this field, the use of radiolabeled ligands has remained so far the gold-standard method. Here the authors report a less hazardous alternative for high-throughput screening (HTS) applications by the setup of a nonradioactive fluorescencebased technology named Tag

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d-myo-Inositol 1-phosphate as a surrogate of d-myo-inositol 1,4,5-tris phosphate to monitor G protein-coupled receptor activation

Trinquet¹,

Fink²,

Bazin³

et al. 2006

Analytical Biochemistry

121

122

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