Multicolor time‐resolved Förster resonance energy transfer microscopy reveals the impact of GPCR oligomerization on internalization processes

Faklaris, Orestis; Cottet, Martin; Falco, Amandine; Villier, Brice; Laget, Michel; Zwier, Jurriaan M.; Trinquet, Eric; Mouillac, Bernard; Pin, Jean‐Philippe; Durroux, Thierry

doi:10.1096/fj.14-260059

Cited by 40 publications

(39 citation statements)

References 40 publications

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“…In primary cultures of hippocampal neurons, co-expression of CLIP-mGlu2 and SNAP-mGlu4 subunits could be detected at the cell surface through labeling with CLIP and SNAP substrates carrying either Lumi4-Tb or Red. In these neurons, using a lanthanide-based time-resolved FRET microscope that we recently developed ( Faklaris et al, 2015 ), we detected a TR-FRET signal between the CLIP and SNAP subunits equivalent to that measured for homodimeric mGlu2 receptors. This observation is consistent with the formation of mGlu2-4 heterodimers in transfected neurons ( Figure 5 ).…”

Section: Resultsmentioning

confidence: 97%

“…Cells were imaged in imaging buffer. Images were acquired with a homebuilt TR-FRET microscope ( Faklaris et al, 2015 ). Briefly, the donor was excited with a 349 nm Nd:YLF pulsed laser at 300 Hz with ~68 µJ/pulse followed by collection of either the donor signal using a 550/32 nm bandpass filter or the TR-FRET signal using a 700/75 nm bandpass filter.…”

Section: Methodsmentioning

confidence: 99%

“…In the present study, we developed two different innovative approaches to characterize the pharmacological and functional properties of mGlu2-4 heterodimers specifically, without any influence of the co-existing mGlu2 and mGlu4 homodimers. We also used an innovative lanthanide-based time-resolved FRET microscopy approach ( Faklaris et al, 2015 ), to demonstrate mGlu2 and mGlu4 can form heterodimers in transfected neurons. Using our heterodimer selective assays, we identified three pharmacological fingerprints that can be used to identify mGlu2-4 heterodimers in native cells.…”

Section: Introductionmentioning

confidence: 99%

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Pharmacological evidence for a metabotropic glutamate receptor heterodimer in neuronal cells

Delgado

Møller

Ster

et al. 2017

eLife

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Metabotropic glutamate receptors (mGluRs) are mandatory dimers playing important roles in regulating CNS function. Although assumed to form exclusive homodimers, 16 possible heterodimeric mGluRs have been proposed but their existence in native cells remains elusive. Here, we set up two assays to specifically identify the pharmacological properties of rat mGlu heterodimers composed of mGlu2 and 4 subunits. We used either a heterodimer-specific conformational LRET-based biosensor or a system that guarantees the cell surface targeting of the heterodimer only. We identified mGlu2-4 specific pharmacological fingerprints that were also observed in a neuronal cell line and in lateral perforant path terminals naturally expressing mGlu2 and mGlu4. These results bring strong evidence for the existence of mGlu2-4 heterodimers in native cells. In addition to reporting a general approach to characterize heterodimeric mGluRs, our study opens new avenues to understanding the pathophysiological roles of mGlu heterodimers.DOI: http://dx.doi.org/10.7554/eLife.25233.001

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Section: Resultsmentioning

confidence: 97%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Pharmacological evidence for a metabotropic glutamate receptor heterodimer in neuronal cells

Delgado

Møller

Ster

et al. 2017

eLife

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“…Subsequent coimmunoprecipitation and time-resolved FRET reveals the physical association and close proximity of GPCRs in heterologous cells (Fig. 1, A-C) (Milligan and Bouvier, 2005;Maurel et al, 2008;Faklaris et al, 2015). Moreover, fusion of bioluminescent, fluorescent proteins, or nonfunctional fragments of these proteins to the C-terminal tail of GPCRs allows close-proximity detection of GPCR dimers and/or oligomers in living cells using bioluminescence resonance energy transfer (BRET), fluorescence resonance energy transfer (FRET), or bimolecular complementation, respectively (Fig.…”

Section: Introductionmentioning

confidence: 99%

G Protein–Coupled Receptor Multimers: A Question Still Open Despite the Use of Novel Approaches

Vischer

Castro

2015

Mol Pharmacol

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Heteromerization of G protein-coupled receptors (GPCRs) can significantly change the functional properties of involved receptors. Various biochemical and biophysical methodologies have been developed in the last two decades to identify and functionally evaluate GPCR heteromers in heterologous cells, with recent approaches focusing on GPCR complex stoichiometry and stability. Yet validation of these observations in native tissues is still lagging behind for the majority of GPCR heteromers. Remarkably, recent studies, particularly some involving advanced fluorescence microscopy techniques, are contributing to our current knowledge of aspects that were not well known until now, such as GPCR complex stoichiometry and stability. In parallel, a growing effort is being applied to move the field forward into native systems. This short review will highlight recent developments to study the stoichiometry and stability of GPCR complexes and methodologies to detect native GPCR dimers.

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“…Various systems have employed flashlamps, UV lasers, or LEDs for pulsed, epi-illumination, and mechanically or electronically gated CCD cameras for wide-field image acquisition (12,13,(15)(16)(17)(18). Time-resolved confocal microscopy has also been explored (19,20).…”

Section: Introductionmentioning

confidence: 99%

Evaluating the Performance of Time-Gated Live-Cell Microscopy with Lanthanide Probes

Rajendran

Miller

2015

Biophysical Journal

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Probes and biosensors that incorporate luminescent Tb(III) or Eu(III) complexes are promising for cellular imaging because time-gated microscopes can detect their long-lifetime (approximately milliseconds) emission without interference from short-lifetime (approximately nanoseconds) fluorescence background. Moreover, the discrete, narrow emission bands of Tb(III) complexes make them uniquely suited for multiplexed imaging applications because they can serve as Förster resonance energy transfer (FRET) donors to two or more differently colored acceptors. However, lanthanide complexes have low photon emission rates that can limit the image signal/noise ratio, which has a square-root dependence on photon counts. This work describes the performance of a wide-field, time-gated microscope with respect to its ability to image Tb(III) luminescence and Tb(III)-mediated FRET in cultured mammalian cells. The system employed a UV-emitting LED for low-power, pulsed excitation and an intensified CCD camera for gated detection. Exposure times of ∼1 s were needed to collect 5-25 photons per pixel from cells that contained micromolar concentrations of a Tb(III) complex. The observed photon counts matched those predicted by a theoretical model that incorporated the photophysical properties of the Tb(III) probe and the instrument's light-collection characteristics. Despite low photon counts, images of Tb(III)/green fluorescent protein FRET with a signal/noise ratio ≥ 7 were acquired, and a 90% change in the ratiometric FRET signal was measured. This study shows that the sensitivity and precision of lanthanide-based cellular microscopy can approach that of conventional FRET microscopy with fluorescent proteins. The results should encourage further development of lanthanide biosensors that can measure analyte concentration, enzyme activation, and protein-protein interactions in live cells.

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Multicolor time‐resolved Förster resonance energy transfer microscopy reveals the impact of GPCR oligomerization on internalization processes

Cited by 40 publications

References 40 publications

Pharmacological evidence for a metabotropic glutamate receptor heterodimer in neuronal cells

Pharmacological evidence for a metabotropic glutamate receptor heterodimer in neuronal cells

G Protein–Coupled Receptor Multimers: A Question Still Open Despite the Use of Novel Approaches

Evaluating the Performance of Time-Gated Live-Cell Microscopy with Lanthanide Probes

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