Homodimerization of Neuropeptide Y Receptors Investigated by Fluorescence Resonance Energy Transfer in Living Cells*

Michaela C. DingerDagger , Jürgen E. BaderDagger , Andreas D. KóborDagger , Antje K. Kretzschmar§, and Annette G. Beck-SickingerDagger

From the Institutes of Dagger  Biochemistry and § Clinical Immunology, University of Leipzig, D-04103 Leipzig, Germany

Received for publication, June 10, 2002, and in revised form, January 8, 2003

    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Up to now neuropeptide Y (NPY) receptors, which belong to the large family of G-protein-coupled receptors and are involved in a broad range of physiological processes, are believed to act as monomers. Studies with the Y1-receptor antagonist and Y4-receptor agonist GR231118, which binds with a 250-fold higher affinity than its monomer, led to the first speculation that NPY receptors can form homodimers. In the present work we used the fluorescence resonance energy transfer (FRET) to study homodimerization of the hY1-, hY2-, and hY5-receptors in living cells. For this purpose, we generated fusion proteins of NPY receptors and green fluorescent protein or spectral variants of green fluorescent protein (cyan, yellow, and red fluorescent protein), which can be used as FRET pairs. Two different FRET techniques, fluorescence microscopy and fluorescence spectroscopy, were applied. Both techniques clearly showed that the hY1-, hY2-, and hY5-NPY receptor subtypes are able to form homodimers. By using transiently transfected cells, as well as a stable cell line expressing the hY2-GFP fusion protein, we could demonstrate that the Y-GFP fusion proteins are still functional and that dimerization varies from 26 to 44% dependent on the receptor. However, homodimerization is influenced neither by NPY nor by Galpha protein binding.

    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

G-protein-coupled receptors (GPCRs)1 represent a superfamily of proteins characterized by seven transmembrane alpha -helices that interact with a family of heterotrimeric GTP-binding proteins, referred to as G-proteins (1). GPCRs are found in a wide range of organisms, and many kind of chemical messengers act through them, for example adrenalin, angiotensin, or neuropeptide Y (NPY). Ligands for GPCRs are involved in a broad range of physiological functions, and their malfunction is responsible for many diseases (2, 3).

Until recently GPCRs were thought to function as monomers. However, a growing number of evidence suggests that they may exist as homodimers and heterodimers (4-9). The existence of homodimers has been shown for several GPCRs including beta 2-adrenergic receptor (10-12), delta - and kappa -opioid receptors (6, 13), metabotropic glutamate receptor 5 (14), calcium-sensing receptor (15-17), m3 muscarinic receptor (18, 19), vasopressin V2-receptor (20), somatostatin (21, 22), and dopamine receptors (23-25). Whereas homodimerization of the somatostatin receptor 5 (21), the delta -opioid receptor (13), and the beta 2-adrenergic receptor (11) are agonist-mediated, dimerization of the kappa -opioid receptor (26) is agonist-independent.

So far photoaffinity labeling (27), cross-linking studies (15, 24), Western blot analysis (14), and immunoprecipitation (17, 28, 29) are the most frequently applied methods for the investigation of receptor homodimerization. Because of the development of new fluorescent dyes, novel fluorescent proteins, and new instrumentation, the fluorescence resonance energy transfer (FRET) obtained a renaissance (30) and could be applied recently for the investigation of receptor dimerization, as well (11, 21, 31). This technique measures the transfer of energy from a donor molecule to an acceptor molecule when they are between 1-10 nm apart (Fig. 1) (32). The FRET technique was successfully applied for the GPCR gonadotropin-releasing hormone receptor (31). Furthermore, FRET was successfully used for the investigation of transmembrane transporters like the serotonin transporter (33) and epidermal growth factor receptor (34).


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Fig. 1.   Schematic diagram of FRET. Energy transfer from the donor (GFP, CFP) to the acceptor molecule (DSRed, YFP) is only possible when the distance is lower than 100 Å (A1, B1). Otherwise, FRET is not measurable (A2, B2).

In the present study, we investigate the hY1-, hY2-, and hY5-NPY receptor subtypes for their ability to form homodimers by direct FRET of receptor-GFP fusion proteins. NPY receptors belong to the rhodopsin-like superfamily of G-protein-coupled receptors (35). So far five distinct NPY receptors have been cloned (Y1, Y2, Y4, Y5, and y6) (36). Their activation results in the inhibition of adenylyl cyclase and in an increase in intracellular calcium concentration. The natural ligand of these receptors is NPY, a 36-amino acid peptide amide that belongs to the family of pancreatic polypeptides (37). NPY modulates numerous physiological processes including regulation of cardiovascular (38) and renal functions, intestinal motility, memory (39), anxiety, seizures, feeding (40), circadian rhythm (41), and nociception. First speculations for homodimerization come from studies with recently reported truncated NPY analogues named ([P30,C31,F32,L34] NPY28-36 and [P30,C31,W32,L34]NPY28-36) (42, 43) that bind after dimerization with a higher affinity to the hY1-receptor. Furthermore, the homodimeric, peptidergic GR231118 (Y1-antagonist, Y4-agonist) obtains a higher affinity for the Y1-receptor than its monomeric form (42, 43).

To investigate homodimerization of NPY receptors by FRET, we generated fusion proteins of the hY1-, hY2-, or hY5-receptor sequence tagged at their carboxyl terminus to the green, cyan, yellow, or red fluorescent protein (GFP, CFP, YFP, DSRed), respectively. The advantage of these proteins is that they have the suited properties to be used as FRET pairs (44-46). CFP and YFP are spectral variants of GFP and have an appropriate spectral overlap of the donor (CFP) emission and the acceptor (YFP) excitation (47). This pair of proteins has been used widely for the investigation of protein-protein interaction (33, 34). The FRET pair with GFP as donor and DSRed as acceptor is a second successfully applied FRET pair (31). Binding and functional studies showed that these receptor-GFP fusion proteins are still active. Furthermore, the establishment of a cell line that stably expresses the hY2-GFP fusion protein was generated to quantify receptor expression and to correlate the number of binding sites to the fluorescence emission. Coexpression of the FRET pair receptors hY1-CFP/hY1-YFP, hY1-GFP/hY1-DSRed, hY2-CFP/hY2-YFP, hY2-GFP/hY2-DSRed, hY5-CFP/hY5-YFP, and hY5-GFP/hY5-DSRed was analyzed by fluorescence microscopy and fluorescence spectroscopy. A significant FRET effect was found with both techniques and both FRET pairs in a receptor subtype-dependent manner. Whereas the hY2-receptor was less prone to dimerization, hY1 and hY5 had a strong tendency. However, the FRET effect was neither dependent on agonist stimulation nor on GTPgamma S incubation as shown by quantitative fluorescence spectroscopy.

    EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Materials

All materials for tissue culture were supplied by Invitrogen. 3H-NPY was purchased from Amersham Biosciences (specific activity 2.59 TBq/mmol). Restriction enzymes and modifying enzymes were from Invitrogen, and forskolin, Pefabloc SC, pepstatin, N-(trans-epoxysuccinyl)-L-leucine-4-guanidinobutylamide (E64), sodium chloride, magnesium sulfate, potassium chloride, 3-isobutyl-1-methylxanthine, and glucose were from Fluka (Taufkirchen, Germany). Bovine serum albumin, bacitracin, puromycin, and HEPES were supplied by Sigma. Oligonucleotides were purchased from MWG-Biotech AG (München, Germany).

Vector Construction

To create human NPY Y1-, Y2-, Y5-receptor fusion proteins with GFP, CFP, YFP, and DSRed, respectively, appropriate expression vectors were cloned. PCR with Taq polymerase was used to amplify the hY1-, hY2-, and hY5-receptor sequences, which are cloned in the pcDNA3 vector (Invitrogen). An amino-terminal primer, 5'-CTGCTTACTGGCTTATCG-3', upstream of the HindIII site of the multicloning site of pcDNA3 was combined with a primer designed against the carboxyl terminus, where the stop codon is replaced by a restriction site and there is an additional codon for alanine. The carboxy-terminal primer, 5'-CGCGGATCCCAGATTTTTTCATTATCATCATTGTTG-3', with a BamHI site, was used for amplifying the hY1-sequence, the carboxy-terminal primer, 5'-CGCGGATCCGCGACATTGGTAGCCTCTG-3', with a BamHI site, was used for amplifying the hY2-sequence, and the antisense primer, 5'-CGCGTCGACCCCATATGAAGACAGTGTATAAG-3', with a SalI site, was used for amplifying the hY5-sequence. After PCR the receptor sequences were subcloned into pCR2.1-TOPO vector (Invitrogen), respectively, amplified, and digested with HindIII and BamHI or HindIII and SalI. To obtain the hY1-pEGFP, hY2-pEGFP, and hY5-pEGFP vectors the plasmid pEGFP-N1 (Clontech) was digested either with HindIII and BamHI or with HindIII and SalI. The digested vector was ligated to the receptor sequences obtained from pCR2.1-TOPO vector, respectively. Expression vectors with the hY1-, hY2-, and hY5-sequence and CFP, YFP, and DSRed, respectively, were cloned in the same way by using the pECFP-N1 vector (Clontech), pEYFP-N1 vector (Clontech), or the pDSRed-N1 vector (Clontech). The constructs were verified by restriction and sequence analysis.

Construction of Positive Control Fusion Proteins

As a positive control for FRET imaging and measurements, we constructed two different fusion proteins of hY1-receptor, GFP and DSRed and hY2-receptor, YFP and CFP. The hY1-GFP-DSRed vector was cloned in two steps. First, a hY1-pEGFP fusion protein without stop codon in the fusion protein sequence was generated. Therefore, the hY1-pEGFP vector was used as template, and PCR was performed with the amino-terminal primer, 5'-ATCTGGGATCCACCGG-3', and the carboxy-terminal primer, 5'-TCCTCCGCGGCCGCTCCCTTGTACAGCTCG-3', to generate the hY1-GFP(-stop) sequence. After digestion the hY1-GFP sequence of the hY1-pEGFP vector was replaced by hY1-GFP(-stop). In the second step the DSRed sequence was amplified by using PCR. Two primers were generated, the sense primer, 5'-GGCGGCGGCGCGGCCGCGATCAATCTCATCACCAGACAGAGATATGGCAAGAGATCCAGCCCTGAGACACTGATTGGCATGGTGCGCTCCTCC-3', with a NotI site and a restriction site for convertase I, and the antisense primer, 5'-GCCTCTAGAGCCCTACAGGAACAGGTGG-3', with a XbaI site. The vector hY1-pEGFP(-stop) was digested with BamHI and XbaI, and the DSRed sequence was subcloned. The construct was verified by restriction and sequence analysis.

For the cloning of the hY2-YFP-CFP vector the pEYFP-CFP-tandem vector, which was a generous gift from Professor Horn (University of Leipzig), was used as backbone, and the hY2-receptor sequence was amplified by PCR. The amino-terminal primer, 5'-GGCGGCGCTAGCATGGGTCCAATAGGTGC-3', with a NheI site, and carboxy-terminal primer, 5'-GGCGGCCTCGAGGGCGACATTGGTAGCCTCTG-3', with a XhoI site, were used for PCR. The hY2-CFP-YFP-tandem was digested with NheI and XhoI, and the hY2-sequence was subcloned. The vector was verified by restriction and sequence analysis.

Cell Culture and Transfection

BHK cells were cultured in Dulbecco's modified Eagle's medium containing 10% fetal calf serum, and CHO cells were grown in 50% Dulbecco's modified Eagle's medium/50% nutrient mix Ham's F-12 with 10% fetal calf serum. The cells were cultured as monolayers in a humidified 5% CO2 atmosphere at 37 °C. BHK and CHO cells do not express endogenous NPY receptors.

For transient transfection cells were seeded in 25-cm2 flasks. At 90% confluency each well was transiently transfected with 13 µg of reporter plasmid DNA using 26 µl of LipofectAMINE 2000 (Invitrogen) according to the manufacturer's instructions. For cotransfection 6.5 µg of each vector was used. For transient transfection 4.7 µg of vector and 9.4 µl of LipofectAMINE 2000 was used for each well of a six-well plate, and 1 µg of vector and 2 µl of LipofectAMINE 2000 was applied for each well of a 24-well plate.

To generate a cell line stably expressing hY2-GFP receptors BHK cells were cotransfected with hY2-GFP and pBabePuro vector (48). Three days after transfection cells were seeded and maintained in medium with 8 µg/ml puromycin. The medium was changed every 4 days. After 4 weeks stable transformants were isolated by FACS sorting with a Vantage SE FACS machine (BD Biosciences). FACS sorting was repeated three times. There was a period of 4 weeks between each sorting. Clonal expression was confirmed by fluorescent microscopy.

Competition Binding Assay

For binding studies BHK or CHO cells were transiently transfected with the corresponding plasmid 24 h before analysis. Cells were resuspended in incubation buffer (minimum essential medium with Earl's salts containing 0.1% bacitracin, 50 mM Pefabloc SC, and 1% bovine serum albumin). 200 µl of the suspension, containing 4.0 × 10-6 cells per ml, were incubated with 25 µl of a 10 nM solution of 3H-propionyl-NPY (specific activity 2.59 TBq/mmol) and 25 µl of NPY in a concentration range of 1 pM to 1 µM. Nonspecific binding was defined in the presence of 1 µM unlabeled NPY. After 1.5 h at room temperature, the incubation was terminated by centrifugation at 1600 × g at 4 °C for 5 min. The pellets were washed once with 400 µl of cold PBS and centrifuged again, and the washed pellets were resuspended in 100 µl of PBS. The cell suspension was mixed with 3 ml of scintillation mixture, and radioactivity was measured by a beta -counter. The IC50 value was calculated with the software Prism 3.0 (Graph Pad). Each experiment was performed in triplicate, and IC50 ± S.E. are shown in Table I.

For saturation experiments BHK cells stably expressing hY2-GFP were incubated with increasing concentrations of 3H-propionyl-NPY between 0.1 pmol and 8 nmol. Nonspecific binding was determined in the presence of 10-6 M unlabeled porcine NPY. The assay was performed three times independently.

Assays for cAMP Concentration

The intracellular amount of cAMP was determined either by using a cAMP enzyme immunoassay (Biotrak, Amersham, Freiburg, Germany) or with a luciferase reporter gene assay. To perform cAMP enzyme immunoassays BHK or CHO cells were transiently transfected with the corresponding plasmid 24 h in advance. When the cells were grown to confluency, they were resuspended in cAMP buffer (145 mM NaCl, 1 mM MgSO4, 5 mM KCl, 10 mM HEPES, 0.5% bovine serum albumin, 10 mM glucose, 0.1 mM 3-isobutyl-1-methylxanthine, pH 7.4, and incubated for 10 min at 37 °C. Then 2 million cells were incubated with 15 µM forskolin and 1 µM NPY for 1 h at 37 °C. Cells were preincubated with 1 µM NPY for 1 h and then forskolin was added. Incubation was stopped by addition of 100 µl of a 1 M solution of HCl. Cell lysis was done by freezing, followed by centrifugation, and the supernatant was diluted 1:5. Reactions were performed according to the protocol of the manufacturer for the cAMP enzyme immunoassay. The optical density was determined with a plate reader (Tecan SpectraFluorPlus) at 450 nm. The assay was done in duplicate and repeated three times. The reporter gene assay using the pCRELuc plasmid (Stratagene) was performed as reported recently (49).

Fluorescence Microscopy

Fluorescence microscopy with cells coexpressing CFP and YFP receptor fusion proteins was done on a Leica DM IRB microscope (Leica, Wetzlar, Germany). BHK cells were seeded on 24-well plates and transiently cotransfected with the corresponding constructs 24 h before studying by fluorescence microscopy. As excitation source a polychrome VI laser from Photonics was used. CFP was excited at 433 nm, and YFP was excited at 513 nm, and emission was detected with different filter sets (AHF Analysentechnik, Tübingen, Germany). A CFP filter with a D480/40 emitter and a 455 DCLP beamsplitter, a YFP filter with an HQ535/30 emitter and a Q515 1p beamsplitter and a FRET filter (emitter D535/30, beamsplitter 455 DCLP) were used. For FRET microscopy studies cells were excited at 433 nm, and for emission detection the YFP filter was used. Cells were washed two times with PBS and covered with 0.5 ml of PBS and then images were taken with a cooled digital Orca-ER camera (Hamamatsu, Herrsching, Germany). For imaging the openlab software (Improvision, Heidelberg, Germany) was used.

For quantitative FRET measurement the method of sensitized FRET was used (34). Calculations of corrected FRET (FRETc) were carried out on a pixel-by-pixel basis for the entire image. The bleedthrough of CFP and YFP through the FRET filter channel was regarded exerting the following equation: FRETc = FRET - (bleedthrough CFP × CFP) - (bleedthrough YFP × YFP). FRETc images are displayed as YFP intensity-modulated images (51) in pseudocolor mode, where red areas display high values of FRET, and blue areas display low values of FRET. The overall intensity of FRET was calculated using openlab software.

Confocal Imaging

General-- BHK cells expressing both NPY receptor-C tail-GFP and NPY receptor-C tail-DSRed were imaged in a 6-well plate in PBS at room temperature in a Zeiss LSM 510 confocal microscope using a water immersion objective. GFP was excited with the 488-nm line of an argon laser, and DSRed was excited with the 568-nm line of a krypton laser. Emission was measured simultaneously in the green channel and in the red channel.

Photobleaching FRET Analysis-- FRET was measured in fixed cells by continuous illumination of the acceptor (red fusion protein) with the 568-nm line of the Kr laser, which was sufficient to bleach the acceptor. Images of GFP were taken before and after the red fluorescent protein was photobleached. The increase of donor fluorescence (green) after receptor (red) bleaching was interpreted as evidence of FRET occurring from GFP to DSRed.

Fluorescence Spectroscopy

The spectrofluorometric studies were carried out at a Fluorolog-3 spectrofluorometer (Jobin Yvon Spex, Longjumeau, France). For excitation a 450-watt xenon lamp was used.

To study FRET effects between the different NPY receptor subtypes BHK cells were seeded in 25-cm2 culture flasks. The cells were transiently cotransfected with equal amount of the same receptor subtype fused to CFP and YFP, respectively, 24 h before measurements.

The cells were washed with PBS, treated with trypsin/EDTA, and resuspended with Dulbecco's modified Eagle's medium containing fetal calf serum and protease inhibitors (Pefabloc 5 mM, pepstatin 0.7 µg/ml, E64 10 µg/ml). For each measurement 1.0 × 106 cotransfected cells from the same cell pool were incubated with 1 µM, 0.1 µM, and 0.1 nM NPY for 30 min, respectively, and in parallel, the cells were also incubated with 1 µM NPY for 10, 30, and 60 min. To investigate the effect of GTPgamma S cells were incubated with 50, 100, or 500 µM GTPgamma S in the presence of 1 µM NPY for 30 min. After incubation cells were centrifuged at 160 × g at room temperature for 5 min. Then the cell pellets were washed two times with 0.5 ml of PBS and for measurements resuspended in 1 ml of PBS containing protease inhibitors (Pefabloc 5 mM, pepstatin 0.7 µg/ml, E64 10 µg/ml).

For CFP and FRET measurements emission wavelength scans were performed from 450-560 nm with an excitation wavelength of 433 nm. YFP scans were recorded from 510-570 nm with an excitation wavelength of 488 nm.

For the negative control NPY receptor fusion proteins with CFP were cotransfected with the pEYFP-N1 vector, and emission scans were performed at 433- and 488-nm excitation. For transfection 1 µg of the pEYFP vector and 6.5 µg of CFP fusion protein vector were used, which resulted in a higher expression of YFP.

Fluorescence derived from non-transfected cells and equipment was subtracted from each sample to obtain specific fluorescence. The emission spectra at 433-nm excitation were normalized to the CFP fluorescence peak at 475 nm.

    RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Vector Construction

For the investigation of NPY receptor homodimerization by FRET technique different fusion constructs of the hY1-, hY2-, and hY5-receptor and GFP, CFP, YFP, and DSRed, respectively, were cloned. To obtain fusion proteins PCR was used to amplify the receptor sequences. The receptor sequences were subcloned into the expression vectors with GFP, CFP, YFP, and DSRed, respectively. The primers were generated by first removing the stop codon of the receptor sequences and second including restriction sites that allow an in-frame cloning. The cloning was proven by restriction analysis and sequencing. The sequencing data showed that there was no mutation for the hY1-receptor. For the hY2-receptor we could find three mutations (two silent at position Ile-195 and Ile-312 and one conservative mutation K206T). Three mutations were found, as well, for hY5-receptor (one silent at position Asp-31 and two mutations I143T and the consecutive R286K). All mutants, however, were fully functional. Expression and plasma membrane localization of the fusion proteins was confirmed by confocal laser scanning microscopy (see Fig. 3A).

Characterization of BHK Cells Stably Expressing hY2-GFP Fusion Protein

To establish a cell line that stably expresses the hY2-GFP fusion protein, BHK cells were transfected with hY2-pEGFP vector and cultivated in selection medium. Positive clones were separated by using preparative FACS techniques. Cells expressing the NPY receptors were tested by using radioligand binding assay, and GFP expression was investigated by fluorescence microscopy. An IC50 value of 2.6 ± 1.3 was determined by using 3H-propionyl-NPY and unlabeled NPY in a competition assay (Fig. 2C). For determination of the Kd value saturation experiments were performed. A typical saturation curve and Scatchard analysis of 3H-propionyl-NPY binding to BHK cells stably expressing the hY2-receptor fusion protein (hY2-GFP/BHK) is shown in Fig. 2. Kd value of 0.45 ± 0.15 nM and 7063 ± 764 binding sites/cell were calculated after Scatchard analysis.


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Fig. 2.   Characterization of BHK cells stably expressing the hY2-GFP fusion protein. A, saturation curve; B, Scatchard analysis. A Kd value of 0.45 ± 0.15 nM and 7063 ± 764 binding sites/cell were calculated. An IC50 value of 2.6 ± 1.3 nM for NPY was determined (C).

Functionality of NPY Receptor Fusion Constructs

To prove whether the fusion proteins are still functional competition assays for binding and cAMP assays as functional assay were performed. The competition assays showed that all fusion proteins can still bind the natural ligand NPY. The IC50 values of all receptor fusion proteins are shown in Table I, and these values are comparable with IC50 values from binding studies with the wild type (wt) receptors. For the hY1(wt)-receptor an IC50 of 1.6 ± 0.5 nM, for the hY2(wt)-receptor an IC50 of 5.4 ± 1.1 nM, and for the hY5(wt)-receptor an IC50 of 7.22 ± 5.0 nM was determined.


                              
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Table I
NPY binding properties of fusion proteins

The cAMP assays confirmed that all fusion proteins are still active and still inhibit adenylyl cyclase. NPY receptors are Gi-coupled receptors and act through inhibition of adenylyl cyclase. This was measured by the inhibition of forskolin-stimulated cAMP accumulation after receptor activation. Forskolin itself is a natural activator of the adenylyl cyclase. The inhibition of the adenylyl cyclase was found for all receptor fusion proteins after incubation with NPY (data not shown). This confirms that the receptors can still interact with the Gi-proteins and subsequently inhibit the adenylyl cyclase.

Fluorescence Microscopy

Investigation of Coexpressed NPY Receptor Fusion Proteins-- BHK cells were transiently cotransfected with the FRET pairs CFP/YFP and GFP/DSRed fused to the NPY receptor subtypes, respectively. If molecules of GFP/DSRed and CFP/YFP come into appropriate physical proximity, energy transfer from CFP to YFP and GFP to DSRed will take place (Fig. 1), and yellow or red fluorescence will be visible. Accordingly, if receptors are present as individual monomers, their fluorescence will not be effected by each other.

Fluorescence microscopy was used to perform FRET studies in living cells. Images were taken from cells cotransfected with NPY receptors fused to the FRET pair CFP/YFP. Using the corresponding donor and acceptor filter sets CFP and YFP are visible (Fig. 3B). Furthermore the expression of this FRET pair is not interfering with each other. To investigate NPY receptor interaction images were taken with the FRET filter set. A weak yellow fluorescence was obtained from cells cotransfected with hY1-, hY2-, and hY5-receptors fused to CFP and YFP, respectively (Fig. 3B). The fluorescence images taken with the FRET filter also showed that the fluorescence intensity of the hY1- and hY5-receptor-transfected cells was stronger than the fluorescence from hY2-receptor-transfected cells, whereas the conditions were equal for all systems.


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Fig. 3.   Fluorescence microscopy studies. A, BHK cells were transiently cotransfected with hY1-GFP and hY1-DSRed fusion proteins, and images were acquired through GFP (A1) and DSRed (A2) channels using confocal laser scanning microscopy. A3 represents an overlay of the GFP and DSRed channel. B, BHK cells were transiently cotransfected with equal amounts of the same NPY receptor subtype fused to the FRET pair CFP/YFP. One day after transfection, cells were washed with PBS, and images were taken with appropriate filter sets. B1 images show hY1-CFP/hY1-YFP, B2 images show hY2-CFP/hY2-YFP, and B3 images show hY5-CFP/hY5-YFP cotransfected cells. Images were taken with the donor filter set (left column), with the acceptor filter set (middle column), and with the FRET filter set (right column). C, hY5-CFP and hY5-YFP receptor fusion proteins were transiently coexpressed in BHK cells. Images were taken by the CFP filter (left column), YFP filter (middle column), and the FRET filter. FRETc was calculated as described under "Experimental Procedures" and is presented as pseudocolor intensity-modulated images (FRETc/YFP; right column).

We suggest that the weak yellow fluorescence is an effect of FRET and results from a close contact between the receptor subtypes. For negative controls, cells expressing only YFP or CFP fusion proteins were investigated with the appropriate FRET filter, as well. We observed no yellow fluorescence by using the same FRET filter and the same conditions as above (Fig. 4, A and B).


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Fig. 4.   Negative and positive controls. BHK cells were transiently transfected with hY1-CFP (A1) and hY1-YFP (B1), respectively, and images were taken with the corresponding filter sets. The same cells were used for imaging with the corresponding FRET filter (A2-B2), and no yellow fluorescence is visible. Similar studies were also performed for hY2- and hY5-fusion proteins and showed the same results (data not shown). As positive control BHK cells were transiently transfected with the hY2-YFP-CFP-tandem (D). Images were taken with the corresponding filter sets (D1/2), and FRET was visible as yellow fluorescence (D3). The hY2-YFP-CFP-tandem was used for fluorescence spectroscopy, and an emission scan with 433-nm excitation was performed (C).

Furthermore, for positive control BHK cells were transfected with the hY2-YFP-CFP fusion protein, and fluorescence images were taken with the corresponding filter set. The expression of the FRET partners was not disturbed, and yellow and cyan fluorescence was obtained. By taking the FRET filters a yellow fluorescence was observed (Fig. 4D, comparable with the one in Fig. 3B).

Effect of NPY-- To study NPY-induced FRET effect BHK cells were cotransfected with hY1-GFP and hY1-DSRed fusion protein. Cells were covered with medium containing 1 µM NPY and incubated for 30 min. Images were taken and compared with images from non-stimulated cells. No increase or decrease of fluorescence intensity was observed (data not shown).

Quantitative FRET Measurement-- To quantify FRET the efficiency of energy transfer between CFP and YFP was measured by calculating the sensitized FRET signal (FRETc) on a pixel-by-pixel basis as described under "Experimental Procedures" (50). A strong energy transfer was found for the positive control, and the lowest energy transfer was found for the negative control. A strong energy transfer is illustrated with the red color, and a low intensity is illustrated with the blue color. Furthermore the green color of NPY receptor cotransfected cells indicates that there is an energy transfer.

Photobleaching Studies-- The method of photobleaching is a sufficient application for the investigation of FRET (21). FRET can occur only in the presence of an acceptor molecule. If the acceptor is removed or destroyed, it would be predicted that the fluorescence of the donor would increase upon illumination. For photobleaching studies the FRET pair GFP (donor) and DSRed (acceptor) fused to the Y5-receptor, respectively, was used. After a strong illumination of DSRed we observed an decrease of red fluorescence and 30% increase of the green fluorescence.

Fluorescence Spectroscopy

Investigation of NPY Receptor Fusion Proteins-- To quantify the FRET effect and to verify the results obtained from fluorescence microscopy FRET studies were performed with a spectrofluorometer in living cells. For measurements the cells were cotransfected with the same NPY receptor subtype fused to CFP and YFP, respectively. Under these conditions FRET should be observed if CFP and YFP were in close proximity.

Cells cotransfected with the hY5-receptor fusion proteins were excited at 433 nm, and emission scans were performed. The spectra showed a shoulder at 475 and 505 nm, the emission shoulder of CFP. A third significant peak was found at 527 nm, the emission maximum of YFP (Fig. 5, A1, blue line and B). The emission scan of cells only expressing the hY5-CFP receptor fusion protein showed only the emission shoulder at 475 and 505 nm; the YFP emission peak at 527 nm was not observed (Fig. 5, A1, brown line and B). Emission scans were also performed with cells coexpressing the hY1- and the hY2-receptor fusion proteins, respectively. For all receptor subtypes the emission shoulder at 475 and 505 nm was recorded, as was the significant peak at 527 nm (Fig. 5B). In parallel emission scans were performed with cells expressing the hY1- and hY2-receptor CFP fusion protein, respectively, and the obtained spectra show only the emission shoulder at 475 and 505 nm (Fig. 5B). For the hY1- and the hY5-receptor fusion proteins a stronger peak at 527 nm was obtained after normalization of the spectra to the emission maxima at 475 nm than for the hY2-receptor (Fig. 5, A, red arrows and B).


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Fig. 5.   FRET studies performed with fluorescence spectroscopy. BHK cells were transiently cotransfected with the same NPY receptor subtype fused to the FRET pair CFP/YFP. Whole cells were used for measurements with a spectrofluorometer. The emission spectra were recorded with an excitation at 433 nm for FRET and an excitation at 488 nm for normal YFP fluorescence. The detection of the FRET effect is at 527-nm emission. A, spectra recorded from cells cotransfected with the hY5-receptor fused to CFP and YFP by using different conditions. B, calculated ratio of the fluorescence intensity at 475/527 nm obtained from recorded fluorescence spectra by using cotransfected BHK cells (hatched, hY1; solid, hY2; striped, hY5). C, BHK cells were transiently cotransfected with different amounts of NPY receptor fusion protein DNA, and emission spectra were recorded. The ratio of the fluorescence intensity 475/527 nm is shown (hatched, hY1; solid, hY2; striped, hY5).

For negative control cells were cotransfected with the hY1-, hY2-, or the hY5-receptor fused to CFP and with untagged YFP, respectively. YFP in this case is only expressed in the cytoplasm, and therefore, no strong interaction between the receptor fusion protein and YFP is expected. Recorded emission wavelength scans with excitation at 433 nm showed that there is no significant peak at 527 nm (Fig. 5, A, green lines and B).

The emission spectrum of the positive control, hY2-YFP-CFP-tandem, at 433-nm excitation shows the typically shoulder at 475 and 505 nm, obtained from CFP, and a strong peak at 527 nm (Fig. 4C). Because of the distance of YFP and CFP this peak can only result from FRET and is considered to be the maximal FRET.

Taken together, hY1-, hY2-, and hY5-receptor fusion proteins show a significant FRET-derived increase at 527 nm, indicating that the receptors form dimers or heterodimers. The strongest fluorescence intensity at 527 nm was observed in cells expressing the hY1- and the hY5-receptor fusion proteins, respectively. This effect was not derived from different receptor expression as confirmed from emission spectra (Fig. 5, A4, A5, and A6).

Effect of the Natural Ligand NPY-- To investigate a possible ligand-induced increase or decrease of fluorescence intensity at 527 nm (FRET) after excitation at 433 nm cotransfected cells were stimulated with NPY by using different conditions.

First, concentration-dependent-induced fluorescence intensity was investigated. BHK cells were cotransfected with the hY5-CFP and hY5-YFP fusion protein and incubated with different NPY concentrations for the same incubation time. Only cells from the same cotransfected cell pool were used for the measurements. Nearly the same fluorescence intensity at 527-nm emission was obtained for the different NPY concentrations (1 µM, 10 nM, and 0.1 nM) (Fig. 5, A1 and B). The small differences of the spectra are caused by transfected cells, because each cell does not express exactly the same amount of receptor fusion proteins. Furthermore, cells cotransfected with the hY5-receptor fusion proteins were incubated with 1 µM NPY for different incubation times (10, 30, and 60 min). Performed emission scans with excitation at 433 nm show again no difference in the emission spectra (Fig. 5, A2 and B). No increase or decrease of FRET fluorescence intensity at 527 nm was observed. However, the fluorescence intensity was still significantly stronger than the fluorescence intensity of the negative control. The same approaches were performed for BHK cells coexpressing the hY1- and the hY2-receptor fusion proteins, respectively. No differences in the recorded spectra were found for hY1-receptor fusion proteins. There was no increase or decrease of the FRET fluorescence intensity at 527 nm (Fig. 5B). The same was found for cells cotransfected with the hY2-fusion proteins (Fig. 5B). Accordingly, the oligomerization of the receptor is not effected by NPY.

Effect of NPY and GTPgamma S-- In further studies cotransfected cells were incubated with different concentrations of GTPgamma S in the presence of 1 µM NPY for 30 min. GTPgamma S is an analog of GTP, and after binding to the G-protein hydrolization is not possible anymore. Therefore, the G-protein stays in the activated form and is no longer accessible for the receptor.

For all three receptor subtypes no significantly different spectra were measured from cells stimulated with different concentrations of GTPgamma S (Fig. 5, A3 and B). The slight variations are not statistically significant and are rather because of the transiently cotransfected cells.

Receptor Density of Transfected Cells-- From investigation with BHK cells stably expressing the hY2-GFP receptor fusion protein, we know that each cell expresses around 7000 binding sites. Correlation of the extinction coefficient of GFP at 489 nm excitation (epsilon  = 55000) and fluorescence intensity at 513 nm allowed us to roughly estimate binding sites in transiently transfected cells. Around 25400 binding sites could be calculated for transiently transfected BHK cells with hY2-GFP (Table II). Assuming that an average diameter of a BHK cell is 10 µm, and the surface of a GPCR is around 3 nm (helix-diameter, 0.5 nm) the mean distance between two receptors should be ~250 nm in case of equal distribution. This is by far more distant than the half-maximal FRET of 4.7 or 4.9 nm for CFP/YFP or GFP/DSRed pairs, respectively (45).


                              
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Table II
Calculated binding sites of transiently transfected BHK cells
From saturation studies of BHK cells stably expressing hY2-GFP receptors, the amount of binding sites is known. Using the same amount of cells, the given varepsilon 488 of GFP (55000) and the measured fluorescence intensity at 509-nm emission the calculation of binding sites of transiently transfected cells expressing hY2-GFP fusion protein is possible. In parallel, because of the measurement of fluorescence intensity, we calculated the receptor density of cells cotransfected with NPY receptors tagged with CFP and YFP, respectively, because the varepsilon 433 of CFP (26000) and varepsilon 488 YFP (42500) is also known.

In parallel it was possible to determine the amount of receptors from cells that were transiently transfected with the CFP and YFP fusion proteins alone or together by using epsilon 488 (42500 for YFP) and epsilon 433 (26000 for CFP) as shown in Table II. The total amount of receptors, expressed by cotransfected cells, is lower than 25410 in any case. Cells cotransfected with hY1-receptor fusion proteins express the lowest amount of receptors. Furthermore, we investigated a lower expression rate for the CFP fusion proteins for cells cotransfected with the hY1- and hY5-receptor fusion proteins, respectively, than for the receptors fused to YFP. Cells cotransfected with hY2-receptor tagged with CFP and YFP express nearly the same amount of both fusion proteins.

Cells were also cotransfected with different amounts of receptor fusion protein DNA (1, 3, 6.5, 13 µg), and the same amount of each receptor subtype fused to CFP and YFP, respectively, was used. The same fluorescence intensity at 527 nm after excitation with 433 nm was observed independent from the DNA concentration (Fig. 5C). Accordingly, the FRET effect is independent from the amount of receptor expression. The very low signals for the hY1-receptor using 1 and 13 µg of DNA is caused by an extremely low transfection rate found in these cases. In any case, it can be clearly excluded that FRET occurs only from the close distance because of the overexpression of the receptor fusion proteins.

    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The first speculations on homodimerization of NPY receptors come from studies on the hY1-receptor antagonist GR231118 (42) and from studies with two peptide ligands, [P30,C31,F32,L34] NPY28-36 and [P30,C31,W32,L34]NPY28-36, selective for the hY1- and the hY4-receptors. GR231118, a homodimer of the carboxy-terminal part of NPY, shows a much higher affinity for the hY1-receptor than the monomer. The same result was found for the two truncated NPY analogues, [P30,C31,F32,L34] NPY28-36 and [P30,C31,W32,L34]NPY28-36, which bind as dimers with a higher affinity to the hY1-receptor than as monomer. We assumed that homodimerization of the hY1-receptor could be the reason for the higher affinity. Thus, we decided to investigate homodimerization of the NPY receptor subtypes. Published data demonstrate that FRET is a suitable technique for the investigation of protein-protein interaction (33, 34, 52, 53). Accordingly, NPY receptors tagged with GFP variants, which can be used as FRET pairs, were generated.

After the successful cloning of the receptor fusion proteins mammalian cells were transfected with the cloned fusion proteins, and binding studies, as well as cAMP studies, were performed. These functional studies proved that the receptor fusion proteins are still active and functional. Fluorescent proteins that are expressed in the cytoplasm, in parallel, do not influence the binding behavior of NPY to the hY1-, hY2-, and hY5-receptors. The IC50 values calculated from binding studies at the fusion proteins are comparable with the IC50 values calculated from binding studies with the wt receptors. The inhibition of cAMP demonstrates that the tagged receptors are still able to bind to G-proteins that inhibit the adenylyl cyclase. The signal transduction process is obviously not disturbed by the fluorescent proteins.

After investigation of cotransfected cells that express hY1-, hY2-, and hY5-FRET pairs, respectively, a FRET effect was observed by using fluorescence microscopy, as well as fluorescence spectroscopy. FRET effect was observed for all three different NPY receptor subtypes, for the hY1-, hY2-, and hY5-receptor. We suggest that these FRET effects are caused by receptor homodimerization or oligomerization, because FRET is only possible when the distance between the FRET pairs is very low. The performed negative controls from fluorescence microscopy and fluorescence spectroscopy confirm that FRET is not an effect of the fluorescence proteins itself. FRET was only obtained for cells containing receptor fusion protein pairs or receptor-tandem constructs produced as positive control.

The signal at 527 nm was also not an effect of YFP itself. Spectra recorded with excitation from YFP alone (433-nm) showed a much lower signal at 527-nm emission compared with spectra of cotransfected cells. Furthermore, the FRET fluorescence intensity of the negative control at 527 nm is much lower although the YFP expression itself is much stronger compared with cotransfected cells (Fig. 5, A4, A5, and A6, green lines versus all other lines). Accordingly, the maxima at 527 nm cannot be caused by the receptor-YFP fusion proteins.

Furthermore, the existence of FRET between the chosen FRET pairs is confirmed by the generated positive controls containing the FRET pairs in the same molecule. Comparing the results from cells cotransfected with receptor fusion proteins and with the positive control, respectively, identical images from fluorescence microscopy and the identical shape of the fluorescence spectra were obtained. As expected, the emission maxima at 527 nm from the positive control was stronger compared with the signal from cotransfected cells, because every single FRET pair provokes an energy transfer. Subsequently this was taken as the maximal FRET.

The calculation of the receptor density on the cell surface of cotransfected cells and the cotransfection of cells with different DNA concentrations showed that the measured FRET effect is not an effect of receptor overexpression. The average distance between two isolated receptors should be so far that no FRET effect can be recognized.

To investigate a ligand-induced FRET effect cells were cotransfected with each receptor subtype tagged with the FRET pairs, respectively, and incubated with different concentrations of NPY or for different periods. The applied NPY concentrations were chosen in that way, such that different numbers of occupied NPY receptors were obtained. The IC50 value of NPY for the used receptors is around 1 nM. Therefore, in case of 1 µM NPY nearly all receptors are occupied, and using 10 and 0.1 nM, accordingly less. The different incubation periods allow the detection of a fast or slow FRET effect. However, all recorded spectra presented no significant difference at 527-nm emission. No increase or decrease of the FRET effect was found for any receptor. For the hY1-receptor no ligand-induced increase or decrease of FRET was observed from fluorescence spectroscopy, as well as from fluorescence microscopy.

Furthermore cotransfected cells expressing the receptor fusion proteins were incubated with different concentrations of GTPgamma S in the presence of the same concentration of NPY, respectively. Again for all receptor subtypes no change of the FRET effect was measured. Taken the results from the fluorescence spectroscopy after NPY and NPY/GTPgamma S stimulation together we suggest that NPY receptor homodimerization of the investigated receptor subtypes is induced neither by NPY nor by GTPgamma S. We speculate that the receptors are not transported in the single form to the cell membrane, and therefore they do not form dimers after ligand stimulation. Accordingly, NPY receptors assemble as dimeric units in the endoplasmatic reticulum already, and the receptors are transported as homodimers to the cell membrane.

For the hY1- and the hY5-receptors a stronger emission maximum at 527 nm was recorded, which results from FRET. The ratio between the emission maxima at 527 and 475 nm was determined. The maximum at 475 nm was used for the ratio calculation. A high ratio reflects a high dimerization rate or a smaller distance between the fluorescence molecules. Accordingly, we suggest that the dimerization state of hY1- and hY5-receptors is higher than that from the hY2-receptors supposing that the distances between the fusion proteins are the same. This can be assumed because of the same overall organization of the receptor fusion proteins; however, a difference in orientation cannot be fully excluded. Calculation based on 100% FRET of the tandem suggests 41-44% receptor dimers for Y1 and Y5 versus 26% for the Y2-receptor (Table III) whereas it has to be kept in mind that percentages might be influenced, as well, by a different geometry of tandem and dimer, as well as by CFP-CFP and YFP-YFP dimers. However, comparing the different receptor subtypes, it became clear that approximately half as many Y2-receptors are present in dimers compared with Y1- and Y5-receptors. The same result was obtained from fluorescence microscopy by pixel-to-pixel analysis and photobleaching in case of the Y5-receptor. Although the expression rate of the hY1-receptor is the lowest of the investigated receptor subtypes, the dimerization state is higher than that of the hY2-receptor. Furthermore, cells cotransfected with hY2-receptor FRET pair express the highest amount of hY2-CFP fusion protein compared with the other two receptor subtypes. However, this higher amount of the FRET donor does not result in an increased FRET effect. Accordingly, the number of receptors does not influence the dimerization state, but the dimerization state is dependent on the receptor subtype. As the hY1- and the hY5-receptors are involved in some identical physiological roles like regulation of food intake dimerization can be speculated to be correlated with function. Furthermore, subtype-specific dimerization could lead to subtype-specific receptor internalization or recycling, when more than one receptor is expressed on cells.


                              
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Table III
Ratio of fluorescence intensity at 527 and 475 nm
Spectra were recorded as described under "Experimental Procedures." The ratio between the maxima at 527 nm (FRET) and the maxima at 475 nm (CFP) was calculated. The higher the ratio527/475 the higher the effect of FRET. The highest ratio was calculated for the tandem, and the dimerization rate was set to 100%. Correspondingly, the dimerization rate of the cotransfected cells could be calculated.

Galzi and co-workers (54) also generated an NPY hY1-receptor fusion protein with GFP. In this case the hY1-receptor was labeled at the amino terminus and not at the carboxyl terminus. This fusion protein was successfully applied for the investigation of receptor internalization and for measurements with a spectrofluorometer. These data confirm that NPY receptor fusion proteins with GFP are useful tools for the investigation of NPY receptors.

In summary our data show for the first time that NPY receptors fused with GFP or GFP variants at the carboxy-terminal part are still fully functional. They are able to bind the natural ligand and able to activate second messengers.

In addition, the establishment and characterization of a cell line that stably expresses the hY2-GFP fusion protein was successful. This will be a useful tool to further characterize receptor internalization and production.

Furthermore, the fusion proteins were successfully applied for the investigation of receptor interaction. We used two different FRET pairs and different FRET techniques for these investigations, which led to the same results. After cotransfection of cells with the hY1-, hY2-, and hY5-receptor subtypes fused to the FRET pairs, respectively, FRET was observed for each NPY receptor subtype, and we suggest that the FRET effect is caused by receptor dimerization. FRET was not induced by NPY, and also stimulation with GTPgamma S/NPY did not influence FRET.

In conclusion, we suggest that the hY1-, hY2-, and hY5-NPY receptors subtypes are able to form homodimers and that the homodimerization is induced neither by the ligand nor by GTPgamma S. Further studies on receptor heterodimerization are currently in progress.

    ACKNOWLEDGEMENTS

We thank Hella Späte for excellent technical assistance in cell culture and Dr. Jens Grosche for confocal microscopy.

    FOOTNOTES

* This work was supported by Fond der chemischen Industrie, the Human Frontiers Science Program (RG 45-2000B), and by Grant Be 1264/5-1 from the Deutsche Forschungsgemeinschaft.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

This paper is dedicated to Professor Günther Jung, University of Tübingen, on the occasion of his 65th birthday.

To whom correspondence should be addressed: Inst. of Biochemistry, University of Leipzig, Talstr. 33, D-04103 Leipzig, Germany. Tel.: 49-341-9736-900; Fax: 49-341-9736-998; E-mail: beck-sickinger@uni-leipzig.de.

Published, JBC Papers in Press, January 10, 2003, DOI 10.1074/jbc.M205747200

    ABBREVIATIONS

The abbreviations used are: GPCR, G-protein-coupled receptor; BHK, baby hamster kidney; CFP, cyan fluorescent protein; CHO, Chinese hamster ovary; DSRed, red fluorescent protein; FRET, fluorescence resonance energy transfer; GFP, green fluorescent protein; NPY, neuropeptide Y; YFP, yellow fluorescent protein; EGFP, enhanced GFP; FACS, fluorescence-activated cell sorter; PBS, phosphate-buffered saline; FRETc, corrected FRET; GTPgamma S, guanosine 5'-3-O-(thio)triphosphate; wt, wild-type.

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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